Lack of Diversity in Transplant Hepatology Fellowship Program Directorship

BACKGROUND

Diversity in medicine has garnered significant attention in recent medical workforce research, as studies consistently reveal the beneficial impact of race-concordant visits on patient outcomes, adherence, and satisfaction. While diversity among residency and fellowship program directors has been studied in other fields, little is known about the diversity within niche fellowship programs such as transplant hepatology. This study aims to investigate the demographic information of program directors in transplant hepatology fellowship programs.

METHODS

We identified transplant hepatology fellowship programs and their program directors from the American College of Gastroenterology website. Multiple reviewers compiled demographic and training information from internet searches, which was analyzed using chi-square analysis. In assessing racial diversity, researchers identified perceived race using multiple indicators, including name, physical appearance, and affiliation with identity associations.

RESULTS

Our study analyzed data from 72 program directors, with 61.11% being male. Among the program directors, 55.6% appeared non-Hispanic White, 36.11% appeared Asian, while apparent Hispanics and Blacks represented 5.56% and 4.17%, respectively. Our analysis also found that male program directors appeared largely non-Hispanic white (72.72%) and were significantly more likely to be professors (p = 0.045) rather than associate or assistant professors.

DISCUSSION

Our findings indicate that transplant hepatology fellowship programs are primarily led by male and non-Hispanic White physicians. To attract underrepresented medical students and residents, it is critical to make meaningful efforts to improve diversity and ensure equitable representation of leaders. Future research should focus on developing strategies to build a more inclusive workforce while addressing existing leadership inequities.

Temperature sensing by the dsrA promoter

Synthesis of the small regulatory RNA DsrA is under temperature control. The minimal dsrA promoter of 36 bp contains sufficient information to ensure such regulation. In vivo, we have analyzed the critical elements responsible for the temperature control of dsrA by using a collection of chimeric promoters combining various elements of the dsrA promoter and the lacUV5 promoter, which does not respond to temperature. Our results favor an RNA polymerase-DNA interaction model instead of a trans-acting factor for temperature regulation. While all of the elements of the dsrA promoter contribute to temperature-sensitive expression, the sequence of the -10 box and the spacer region are the essential elements for the thermal response of the dsrA promoter. The proper context for these promoter elements, including at least one of the flanking elements, the -35 region or the start site region, is also required. Point mutations demonstrate that the sequence of the -10 box imposes constraints on the length and the sequence of the spacer and/or its AT richness, even at low temperature. These results show a complex interdependence of different regions in the promoter for temperature regulation.

Small non-coding RNAs, co-ordinators of adaptation processes in Escherichia coli: the RpoS paradigm

Adaptation to the changing environment requires both the integration of external signals and the co-ordination of internal responses. Around 50 non-coding small RNAs (sRNAs) have been described in Escherichia coli; the levels of many of these vary with changing environmental conditions. This suggests that they play a role in cell adaptation. In this review, we use the regulation of RpoS (sigma38) translation as a paradigm of sRNA-mediated response to environmental conditions; rpoS is currently the only known gene regulated post-transcriptionally by at least three sRNAs. DsrA and RprA stimulate RpoS translation in response to low temperature and cell surface stress, respectively, whereas OxyS represses RpoS translation in response to oxidative shock. However, in addition to regulating RpoS translation, DsrA represses the translation of HNS (a global regulator of gene expression), whereas OxyS represses the translation of FhlA (a transcriptional activator), allowing the cell to co-ordinate different pathways involved in cell adaptation. Environmental cues affect the synthesis and stability of specific sRNAs, resulting in specific sRNA-dependent translational control.

Identification of novel small RNAs using comparative genomics and microarrays

A burgeoning list of small RNAs with a variety of regulatory functions has been identified in both prokaryotic and eukaryotic cells. However, it remains difficult to identify small RNAs by sequence inspection. We used the high conservation of small RNAs among closely related bacterial species, as well as analysis of transcripts detected by high-density oligonucleotide probe arrays, to predict the presence of novel small RNA genes in the intergenic regions of the Escherichia coli genome. The existence of 23 distinct new RNA species was confirmed by Northern analysis. Of these, six are predicted to encode short ORFs, whereas 17 are likely to be novel functional small RNAs. We discovered that many of these small RNAs interact with the RNA-binding protein Hfq, pointing to a global role of the Hfq protein in facilitating small RNA function. The approaches used here should allow identification of small RNAs in other organisms.

Signal transduction cascade for regulation of RpoS: temperature regulation of DsrA

Many environmental parameters modulate the amount of the RpoS sigma factor in Escherichia coli. Temperature control of RpoS depends on the untranslated RNA DsrA. DsrA activates RpoS translation by pairing with the leader of the mRNA. We find that temperature affects both the rate of transcription initiation of the dsrA gene and the stability of DsrA RNA. Both are increased at low temperature (25 degrees C) compared to 37 or 42 degrees C. The combination of these results is 25-fold-less DsrA at 37 degrees C and 30-fold less at 42 degrees C than at 25 degrees C. Using an adapted lacZ-based reporter system, we show that temperature control of transcription initiation of dsrA requires only the minimal promoter of 36 bp. Overall, transcription responses to temperature lead to a sixfold increase in DsrA synthesis at 25 degrees C over that at 42 degrees C. Furthermore, two activating regions and a site for LeuO negative regulation were identified in the dsrA promoter. The activating regions also activate transcription in vitro. DsrA decays with a half-life of 23 min at 25 degrees C and 4 min at 37 and 42 degrees C. These results demonstrate that the dsrA promoter and the stability of DsrA RNA are the thermometers for RpoS temperature sensing. Multiple inputs to DsrA accumulation allow sensitive modulation of changes in the synthesis of the downstream targets of DsrA such as RpoS.

The RssB response regulator directly targets sigma(S) for degradation by ClpXP

The sigma(S) subunit of Escherichia coli RNA polymerase regulates the expression of stationary phase and stress response genes. Control over sigma(S) activity is exercised in part by regulated degradation of sigma(S). In vivo, degradation requires the ClpXP protease together with RssB, a protein homologous to response regulator proteins. Using purified components, we reconstructed the degradation of sigma(S) in vitro and demonstrate a direct role for RssB in delivering sigma(S) to ClpXP. RssB greatly stimulates sigma(S) degradation by ClpXP. Acetyl phosphate, which phosphorylates RssB, is required. RssB participates in multiple rounds of sigma(S) degradation, demonstrating its catalytic role. RssB promotes sigma(S) degradation specifically; it does not affect degradation of other ClpXP substrates or other proteins not normally degraded by ClpXP. sigma(S) and RssB form a stable complex in the presence of acetyl phosphate, and together they form a ternary complex with ClpX that is stabilized by ATP[gamma-S]. Alone, neither sigma(S) nor RssB binds ClpX with high affinity. When ClpP is present, a larger sigma(S)--RssB--ClpXP complex forms. The complex degrades sigma(S) and releases RssB from ClpXP in an ATP-dependent reaction. Our results illuminate an important mechanism for regulated protein turnover in which a unique targeting protein, whose own activity is regulated through specific signaling pathways, catalyzes the delivery of a specific substrate to a specific protease.

Regulation of RpoS by a novel small RNA: the characterization of RprA

Translational regulation of the stationary phase sigma factor RpoS is mediated by the formation of a double-stranded RNA stem-loop structure in the upstream region of the rpoS messenger RNA, occluding the translation initiation site. The interaction of the rpoS mRNA with a small RNA, DsrA, disrupts the double-strand pairing and allows high levels of translation initiation. We screened a multicopy library of Escherichia coli DNA fragments for novel activators of RpoS translation when DsrA is absent. Clones carrying rprA (RpoS regulator RNA) increased the translation of RpoS. The rprA gene encodes a 106 nucleotide regulatory RNA. As with DsrA, RprA is predicted to form three stem-loops and is highly conserved in Salmonella and Klebsiella species. Thus, at least two small RNAs, DsrA and RprA, participate in the positive regulation of RpoS translation. Unlike DsrA, RprA does not have an extensive region of complementarity to the RpoS leader, leaving its mechanism of action unclear. RprA is non-essential. Mutations in the gene interfere with the induction of RpoS after osmotic shock when DsrA is absent, demonstrating a physiological role for RprA. The existence of two very different small RNA regulators of RpoS translation suggests that such additional regulatory RNAs are likely to exist, both for regulation of RpoS and for regulation of other important cellular components.

Posttranslational quality control: folding, refolding, and degrading proteins

Polypeptides emerging from the ribosome must fold into stable three-dimensional structures and maintain that structure throughout their functional lifetimes. Maintaining quality control over protein structure and function depends on molecular chaperones and proteases, both of which can recognize hydrophobic regions exposed on unfolded polypeptides. Molecular chaperones promote proper protein folding and prevent aggregation, and energy-dependent proteases eliminate irreversibly damaged proteins. The kinetics of partitioning between chaperones and proteases determines whether a protein will be destroyed before it folds properly. When both quality control options fail, damaged proteins accumulate as aggregates, a process associated with amyloid diseases.

Redundant in vivo proteolytic activities of Escherichia coli Lon and the ClpYQ (HslUV) protease

The ClpYQ (HslUV) ATP-dependent protease of Escherichia coli consists of an ATPase subunit closely related to the Clp ATPases and a protease component related to those found in the eukaryotic proteasome. We found that this protease has a substrate specificity overlapping that of the Lon protease, another ATP-dependent protease in which a single subunit contains both the proteolytic active site and the ATPase. Lon is responsible for the degradation of the cell division inhibitor SulA; lon mutants are UV sensitive, due to the stabilization of SulA. lon mutants are also mucoid, due to the stabilization of another Lon substrate, the positive regulator of capsule transcription, RcsA. The overproduction of ClpYQ suppresses both of these phenotypes, and the suppression of UV sensitivity is accompanied by a restoration of the rapid degradation of SulA. Inactivation of the chromosomal copy of clpY or clpQ leads to further stabilization of SulA in a lon mutant but not in lon+ cells. While either lon, lon clpY, or lon clpQ mutants are UV sensitive at low temperatures, at elevated temperatures the lon mutant loses its UV sensitivity, while the double mutants do not. Therefore, the degradation of SulA by ClpYQ at elevated temperatures is sufficient to lead to UV resistance. Thus, a protease with a structure and an active site different from those of Lon is capable of recognizing and degrading two different Lon substrates and appears to act as a backup for Lon under certain conditions.

Substrate sequestration by a proteolytically inactive Lon mutant

Lon protein of Escherichia coli is an ATP-dependent protease responsible for the rapid turnover of both abnormal and naturally unstable proteins, including SulA, a cell division inhibitor made after DNA damage, and RcsA, a positive regulator of transcription. Lon is a multimer of identical 94-kDa subunits, each containing a consensus ATPase motif and a serine active site. We found that overexpressing Lon, which is mutated for the serine active site (LonS679A) and is therefore devoid of proteolytic activity, unexpectedly led to complementation of the UV sensitivity and capsule overproduction of a lon deletion mutant. SulA was not degraded by LonS679A, but rather was completely protected by the Lon mutant from degradation by other cellular proteases. We interpret these results to mean that the mutant LonS679A binds but does not degrade Lon substrates, resulting in sequestration of the substrate proteins and interference with their activities, resulting in apparent complementation. Lon that carried a mutation in the consensus ATPase site, either with or without the active site serine, was no longer able to complement a Deltalon mutant. These in vivo results suggest that the pathway of degradation by Lon couples ATP-dependent unfolding with movement of the substrate into protected chambers within Lon, where it is held until degradation proceeds. In the absence of degradation the substrate remains sequestered. Comparison of our results with those from a number of other systems suggest that proteins related to the regulatory portions of energy-dependent proteases act as energy-dependent sequestration proteins.

Regulation by proteolysis: developmental switches

The energy-dependent proteases originally defined in Escherichia coli have proven to have particularly important roles in bacterial developmental systems, including sporulation in Bacillus subtilis and cell cycle in Caulobacter. Degradation of key regulatory proteins participates, with regulation of synthesis and activity of the regulators, to ensure tight control and, where required, irreversible commitment of the cell to specific developmental pathways.

DsrA RNA regulates translation of RpoS message by an anti-antisense mechanism, independent of its action as an antisilencer of transcription

DsrA RNA regulates both transcription, by overcoming transcriptional silencing by the nucleoid-associated H-NS protein, and translation, by promoting efficient translation of the stress sigma factor, RpoS. These two activities of DsrA can be separated by mutation: the first of three stem-loops of the 85 nucleotide RNA is necessary for RpoS translation but not for anti-H-NS action, while the second stem-loop is essential for antisilencing and less critical for RpoS translation. The third stem-loop, which behaves as a transcription terminator, can be substituted by the trp transcription terminator without loss of either DsrA function. The sequence of the first stem-loop of DsrA is complementary with the upstream leader portion of rpoS messenger RNA, suggesting that pairing of DsrA with the rpoS message might be important for translational regulation. Mutations in the Rpos leader and compensating mutations in DsrA confirm that this predicted pairing is necessary for DsrA stimulation of RpoS translation. We propose that DsrA pairing stimulates RpoS translation by acting as an anti-antisense RNA, freeing the translation initiation region from the cis-acting antisense RNA and allowing increased translation.

The ClpXP and ClpAP proteases degrade proteins with carboxy-terminal peptide tails added by the SsrA-tagging system

Interruption of translation in Escherichia coli can lead to the addition of an 11-residue carboxy-terminal peptide tail to the nascent chain. This modification is mediated by SsrA RNA (also called 10Sa RNA and tmRNA) and marks the tagged polypeptide for proteolysis. Degradation in vivo of lambda repressor amino-terminal domain variants bearing this carboxy-terminal SsrA peptide tag is shown here to depend on the cytoplasmic proteases ClpXP and ClpAP. Degradation in vitro of SsrA-tagged substrates was reproduced with purified components and required a substrate with a wild-type SsrA tail, the presence of both ClpP and either ClpA or ClpX, and ATP. Clp-dependent proteolysis accounts for most degradation of SsrA-tagged amino-domain substrates at 32 degrees C, but additional proteases contribute to the degradation of some of these SsrA-tagged substrates at 39 degrees C. The existence of multiple cytoplasmic proteases that function in SsrA quality-control surveillance suggests that the SsrA tag is designed to serve as a relatively promiscuous signal for proteolysis. Having diverse degradation systems able to recognize this tag may increase degradation capacity, permit degradation of a wide variety of different tagged proteins, or allow SsrA-tagged proteins to be degraded under different growth conditions.

Lambda Xis degradation in vivo by Lon and FtsH

Lambda Xis, which is required for site-specific excision of phage lambda from the bacterial chromosome, has a much shorter functional half-life than Int, which is required for both integration and excision (R. A. Weisberg and M. E. Gottesman, p. 489-500, in A. D. Hershey, ed., The Bacteriophage Lambda, 1971). We found that Xis is degraded in vivo by two ATP-dependent proteases, Lon and FtsH (HflB). Xis was stabilized two- to threefold more than in the wild type in a lon mutant and as much as sixfold more in a lon ftsH double mutant at the nonpermissive temperature for the ftsH mutation. Integration of lambda into the bacterial chromosome was delayed in the lon ftsH background, suggesting that accumulation of Xis in vivo interferes with integration. Overexpression of Xis in wild-type cells from a multicopy plasmid inhibited integration of lambda and promoted curing of established lysogens, confirming that accumulation of Xis interferes with the ability of Int to establish and maintain an integrated prophage.

Regulation of proteolysis of the stationary-phase sigma factor RpoS

RpoS, the stationary-phase sigma factor of Escherichia coli, is responsible for increased transcription of an array of genes when cells enter stationary phase and under certain stress conditions. RpoS is rapidly degraded during exponential phase and much more slowly during stationary phase; the resulting changes in RpoS accumulation play an important role in providing differential expression of RpoS-dependent gene expression. It has previously been shown that rapid degradation of RpoS during exponential growth depends on RssB (also called SprE and MviA), a protein with homology to the family of response regulators, and on the ClpXP protease. We find that RssB regulation of proteolysis does not extend to another ClpXP substrate, bacteriophage lambda O protein, suggesting that RssB acts on the specific substrate RpoS rather than on the protease. In addition, the activity of RpoS is down-regulated by RssB when degradation is blocked. In cells blocked for RpoS degradation by a mutation in clpP, cells devoid of RssB show a four- to fivefold-higher activity of an RpoS-dependent reporter fusion than cells overproducing RssB. Therefore, RssB allows specific environmental regulation of RpoS accumulation and may also modulate activity. The regulation of degradation provides an irreversible switch, while the regulation of activity may provide a second, presumably reversible level of control.

Six-fold rotational symmetry of ClpQ, the E. coli homolog of the 20S proteasome, and its ATP-dependent activator, ClpY

ClpQ (HslV) is a homolog of the beta-subunits of the 20S proteasome. In E. coli, it is expressed from an operon that also encodes ClpY (HslU), an ATPase homologous to the protease chaperone, ClpX. ClpQ (subunit Mr 19,000) and ClpY (subunit Mr 49,000) were purified separately as oligomeric proteins with molecular weights of approximately 220,000 and approximately 350,000, respectively, estimated by gel filtration. Mixtures of ClpY and ClpQ displayed ATP-dependent proteolytic activity against casein, and a complex of the two proteins was isolated by gel filtration in the presence of ATP. Image processing of negatively stained electron micrographs revealed strong six-fold rotational symmetry for both ClpY and ClpQ, suggesting that the subunits of both proteins are arranged in hexagonal rings. The molecular weight of ClpQ combined with its symmetry is consistent with a double hexameric ring, whereas the data on ClpY suggest only one such ring. The symmetry mismatch previously observed between hexameric ClpA and heptameric ClpP in the related ClpAP protease is apparently not reproduced in the symmetry-matched ClpYQ system.

Proteases and their targets in Escherichia coli

Proteolysis in Escherichia coli serves to rid the cell of abnormal and misfolded proteins and to limit the time and amounts of availability of critical regulatory proteins. Most intracellular proteolysis is initiated by energy-dependent proteases, including Lon, ClpXP, and HflB; HflB is the only essential E. coli protease. The ATPase domains of these proteases mediate substrate recognition. Recognition elements in target are not well defined, but are probably not specific amino acid sequences. Naturally unstable protein substrates include the regulatory sigma factors for heat shock and stationary phase gene expression, sigma 32 and RpoS. Other cellular proteins serve as environmental sensors that modulate the availability of the unstable proteins to the proteases, resulting in rapid changes in sigma factor levels and therefore in gene transcription. Many of the specific proteases found in E. coli are well-conserved in both prokaryotes and eukaryotes, and serve critical functions in developmental systems.

Role of the heat shock protein DnaJ in the lon-dependent degradation of naturally unstable proteins

We have investigated the role of DnaJ in protein degradation by examining the degradation of intrinsically unstable proteins by Lon protease in vivo. In Escherichia coli, Lon protease is responsible for the rate-limiting step in degradation of highly unstable proteins such as SulA, RcsA, and lambdaN protein, as well as for about 50% of the rapid degradation of abnormal proteins such as canavanine-containing proteins. We found that Lon-dependent degradation of both SulA and lambdaN protein was unaffected in cells lacking functional DnaJ, whereas Lon-dependent turnover of canavanine-containing proteins was slower in dnaJ mutant cells. DnaJ also affected the slow SulA degradation seen in the absence of Lon. The rate of degradation of RcsA was reduced in dnaJ mutants, but both Lon-dependent and Lon-independent degradation was affected; abnormal, canavanine-containing proteins were similarly affected. Both the RcsA that accumulated in dnaJ mutant cells and the SulA that accumulated in lon dnaJ mutant cells was aggregated. The abnormal proteins that partitioned to the insoluble pellet became solubilized over time in dnaJ+ cells but not in dnaJ- cells. Therefore, the co-chaperone DnaJ is not essential for Lon-dependent degradation and may act in protein turnover only as an accessory factor helping to maintain substrates in a soluble form. Such an accessory factor is apparently necessary for abnormal proteins and for RcsA. The relative rates of degradation and aggregation of specific protein targets may determine the importance of the chaperone systems in turnover of a given protein.

ATP-dependent degradation of CcdA by Lon protease. Effects of secondary structure and heterologous subunit interactions

CcdA, the antidote protein of the ccd post-segregational killing system carried by the F plasmid, was degraded in vitro by purified Lon protease from Escherichia coli. CcdA had a low affinity for Lon (Km >/=200 microM), and the peptide bond turnover number was approximately 10 min-1. CcdA formed tight complexes with purified CcdB, the killer protein encoded in the ccd operon, and fluorescence and hydrodynamic measurements suggested that interaction with CcdB converted CcdA to a more compact conformation. CcdB prevented CcdA degradation by Lon and blocked the ability of CcdA to activate the ATPase activity of Lon, suggesting that Lon may recognize bonding domains of proteins exposed when their partners are absent. Degradation of CcdA required ATP hydrolysis; however, CcdA41, consisting of the carboxyl-terminal 41 amino acids of CcdA and lacking the alpha-helical secondary structure present in CcdA, was degraded without ATP hydrolysis. Lon cleaved CcdA primarily between aliphatic and hydrophilic residues, and CcdA41 was cleaved at the same peptide bonds, indicating that ATP hydrolysis does not affect cleavage specificity. CcdA lost alpha-helical structure at elevated temperatures (Tm approximately 50 degrees C), and its degradation became independent of ATP hydrolysis at this temperature. ATP hydrolysis may be needed to disrupt interactions that stabilize the secondary structure of proteins allowing the disordered protein greater access to the proteolytic active sites.

The small RNA, DsrA, is essential for the low temperature expression of RpoS during exponential growth in Escherichia coli

dsrA encodes a small, untranslated RNA. When over-expressed, DsrA antagonizes the H-NS-mediated silencing of numerous promoters. Cells devoid of DsrA grow normally and show little change in the expression of a number of H-NS-silenced genes. Expression of a transcriptional fusion of lacZ to dsrB, the gene next to dsrA, is significantly lower in cells carrying mutations in dsrA. All expression of beta-galactosidase from the dsrB::lacZ fusion is also dependent on the stationary phase sigma factor, RpoS. DsrA RNA was found to regulate dsrB::lacZ indirectly, by modulating RpoS synthesis. Levels of RpoS protein are substantially lower in a dsrA mutant, both in stationary and exponential phase cells. Mutations in dsrA decrease the expression of an RpoS::LacZ translational fusion, but not a transcriptional fusion, suggesting that DsrA is acting after transcription initiation. While RpoS expression is very low in exponential phase at temperatures of 30 degrees C and above, at 20 degrees C there is substantial synthesis of RpoS during exponential growth, all dependent on DsrA RNA. dsrA expression is also increased at low temperatures. These results suggest a new role for RpoS during exponential growth at low temperatures, mediated by DsrA.

Osmotic shock induction of capsule synthesis in Escherichia coli K-12

The genes (cps) involved in the synthesis of the colanic acid capsular polysaccharide in Escherichia coli K-12 are transcriptionally regulated by numerous proteins. Two of these, RcsB and RcsC, share homology with two-component regulatory elements that respond to environmental stimuli. Osmotic shock by sucrose or NaCl transiently increased transcription of a cpsB::lacZ fusion. RcsC and RcsB were essential for osmotic induction of colanic acid synthesis. In contrast to observations in some other osmotically regulated systems, addition of glycine betaine enhanced the osmotic induction of cps::lacZ by both sucrose and NaCl but had no effect alone.

A small RNA acts as an antisilencer of the H-NS-silenced rcsA gene of Escherichia coli

The regulation of capsular polysaccharide synthesis in Escherichia coli K-12 depends on the level of an unstable positive regulator, RcsA. The amount of RcsA protein is limited both by its rapid degradation by Lon, an ATP-dependent protease, and by its low level of synthesis. We have found that the low level of expression from the rcsA promoter is due to transcriptional silencing by the histone-like protein H-NS; this silencing is sensitive to both sequence and context in a region upstream of the -35 region of the promoter. A small (85-nt) RNA, DsrA, when overproduced, activates transcription of rcsA::lacZ fusions by counteracting H-NS silencing. DsrA RNA does not show any extended homology with the rcsA promoter or other sequenced regions of E. coli. Since the stimulation of rcsA transcription by this small RNA does not depend on any sequences from within the rcsA transcript, DsrA acts, either directly or indirectly, on rcsA transcription initiation.

Managing the electronic NIH-guide for grants and contracts

This article describes the implementation of a suite of computer programs to manage and provide access to a database containing the electronic documents that constitute the NIH-Guide that is distributed by the NIH on a weekly basis. The software consists of a management program that reads, processes, and stores the incoming documents and performs erratum updates on existing documents; an alerting program that sends selected information to users who have registered their information needs; a viewer that can be used on the local computer to read these documents; and a World-Wide-Web (WWW) server that can distribute the guide to computers that run WWW client software. The design of the documentation annotations, the management software, and the WWW server are expected to constitute valuable models for similar projects in the future.

A molecular chaperone, ClpA, functions like DnaK and DnaJ

The two major molecular chaperone families that mediate ATP-dependent protein folding and refolding are the heat shock proteins Hsp60s (GroEL) and Hsp70s (DnaK). Clp proteins, like chaperones, are highly conserved, present in all organisms, and contain ATP and polypeptide binding sites. We discovered that ClpA, the ATPase component of the ATP-dependent ClpAP protease, is a molecular chaperone. ClpA performs the ATP-dependent chaperone function of DnaK and DnaJ in the in vitro activation of the plasmid P1 RepA replication initiator protein. RepA is activated by the conversion of dimers to monomers. We show that ClpA targets RepA for degradation by ClpP, demonstrating a direct link between the protein unfolding function of chaperones and proteolysis. In another chaperone assay, ClpA protects luciferase from irreversible heat inactivation but is unable to reactivate luciferase.

Alp suppression of Lon: dependence on the slpA gene

We have previously found that plasmids carrying the Escherichia coli alp gene (now to be called alpA) suppress two phenotypes of a delta lon protease mutant, overproduction of capsular polysaccharide and sensitivity to UV light. Suppression of these lon phenotypes is most likely explained by the increased degradation of the Lon substrates responsible for these phenotypes. We have called this suppressing protease activity Alp protease. The Alp protease activity is detected in cells after introduction of plasmids carrying the alpA gene, which encodes an open reading frame of 70 amino acids. Insertions which abolish Alp activity interrupt this open reading frame. We have used Tn10 and lambda placMu mutagenesis to identify a chromosomal locus, slpA, that is required for alpA+ suppression of delta lon. This locus maps at 57 min, close to the chromosomal location of alpA. The expression of beta-galactosidase from a lac transcriptional fusion to slpA is increased six- to eightfold when the alpA+ gene is present on a multicopy plasmid. Therefore, AlpA acts as a transcriptional regulator of the slpA gene(s); activation of slpA transcription is necessary to suppress the phenotypes of a delta lon mutation. In an accompanying paper (J. E. Kirby, J. E. Trempy, and S. Gottesman, J. Bacteriol. 176:2068-2081, 1994), we show that neither AlpA nor SlpA is a component of the protease itself but that they are part of a regulatory cascade which leads to expression of the Alp protease.

Excision of a P4-like cryptic prophage leads to Alp protease expression in Escherichia coli

The Escherichia coli K-12 alpA gene product, when overproduced from a multicopy plasmid, leads to suppression of the capsule overproduction and UV sensitivity phenotypes of cells mutant for the Lon ATP-dependent protease. This suppression has previously been shown to correlate with increased in vivo activity of a previously unknown energy-dependent proteolytic activity capable of degrading Lon substrates, the Alp protease. We show in an accompanying paper that alpA, which has homology to a short open reading frame in bacteriophage P4, acts as a positive transcriptional regulator of slpA, a gene linked to alpA and necessary for suppression of lon mutants (J. E. Trempy, J. E. Kirby, and S. Gottesman, J. Bacteriol. 176:2061-2067). The sequence of slpA suggests that it encodes an integrase gene closely related to P4 int and that both alpA and slpA are part of a cryptic P4-like prophage. AlpA expression increases SlpA synthesis. Increased SlpA leads, in turn, to the excision and loss of the cryptic prophage. Excision is dependent on integration host factor as well as on SlpA. Prophage excision is necessary but not sufficient for full expression of the Alp protease. A second function (named AHA) allows full protease expression; this function can be provided by the kanamycin resistance element from Tn903 when the element is present on a multicopy plasmid. Excision and loss of the cryptic prophage apparently allow expression of the Alp protease by inactivating a small stable RNA (10Sa RNA) encoded by the ssrA gene. The precursor of this RNA has its 3' end within the cryptic prophage; the mature 3' end lies within the prophage attL site. Inactivation of ssrA by insertional mutagenesis is sufficient to allow expression of the suppressing Alp protease, even in the presence of the cryptic prophage. Therefore, 10Sa RNA acts as a negative regulator of protease synthesis or activity, and prophage excision must inactivate this inhibitory function of the RNA.

An imbalance of HU synthesis induces mucoidy in Escherichia coli

Mutations in a number of loci, including the lon gene, dramatically increase the production of colanic acid capsular polysaccharide and render Escherichia coli K-12 mucoid. The lon gene, which encodes an ATP-dependent protease, is localized at ten minutes on the E. coli map and is very closely linked to the hupB gene coding for one of the two subunits of the histone-like protein HU. Surprisingly the introduction of a multi-copy plasmid carrying either the hupB or hupA gene into a wild-type E. coli strain, results in the overproduction of one of the HU subunits and repression of the synthesis of the other without changing the overall concentration of HU, also renders the cells mucoid. As in a lon strain, the transcription of the cps genes, the structural genes for the synthesis of colanic acid, is induced dramatically. Protease Lon negatively regulates cps genes by destabilizing RcsA, a positive regulator of capsule synthesis. Regulation of HU synthesis does not affect the steady state level of Lon, as judged by Western blotting. The UV sensitivity of the hup transformed lon+ bacteria is identical to the lon+ parental strain, suggesting that Lon activity for the degradation of SulA in these cells is normal. Using lac operon fusions to cps gene promoters and to the rcsA promoter we show that the deregulation of HU synthesis does not by pass the positive regulatory action of RcsA and RcsB for the expression of cps genes but functions by stimulating RcsA synthesis.

A human mitochondrial ATP-dependent protease that is highly homologous to bacterial Lon protease

We have cloned a human ATP-dependent protease that is highly homologous to members of the bacterial Lon protease family. The cloned gene encodes a protein of 963 amino acids with a calculated molecular mass of 106 kDa, slightly higher than that observed by Western blotting the protein from human tissues and cell lines (100 kDa). A single species of mRNA was found for this Lon protease in all human tissues examined. The protease is encoded in the nucleus, and the amino-terminal portion of the protein sequence contains a potential mitochondrial targeting presequence. Immunofluorescence microscopy suggested a predominantly mitochondrial localization for the Lon protease in cultured human cells. A truncated LON gene, in which translation was initiated at Met118 of the coding sequence, was expressed in Escherichia coli and produced a protease that degraded alpha-casein in vitro in an ATP-dependent manner and had other properties similar to E. coli Lon protease.

ClpX, an alternative subunit for the ATP-dependent Clp protease of Escherichia coli. Sequence and in vivo activities

The ATP-dependent Clp protease of Escherichia coli consists of two subunits, the ClpP subunit, which has the proteolytic active site, and ClpA, which possesses ATPase activity and activates the proteolytic activity of ClpP in vitro. Recently, Zylicz and co-workers (Wojtkowiak, D., Georgopoulos, C., and Zylicz, M. (1993) J. Biol. Chem. 268, 22609-22617) identified another E. coli protein that activated ATP-dependent degradation of lambda O protein in the presence of ClpP. The amino-terminal sequence of this protein corresponds to the translated amino-terminal sequence of a gene that we have named clpX. clpX encodes a protein with M(r) 46,300, similar to that observed for the protein purified by Wojtkowiak et al. clpX is an operon with clpP; both genes are cotranscribed in a single heat-inducible 2200-base mRNA, with clpP the promoter proximal gene. The sequence of ClpX includes a single consensus ATP-binding site motif and has limited homology to regions of ClpA and other members of the ClpA/B/C family. A third group of proteins, ClpY, closely related to ClpX, has been identified by sequence homology. Mutations in either clpX or clpP abolish degradation of the highly unstable lambda O protein in vivo. clpX mutants are not defective in degradation of previously identified ClpA/ClpP substrates such as a ClpA-beta-galactosidase fusion protein. It appears that selectivity of degradation by ClpP in vivo is determined by interaction of ClpP with different regulatory ATPase subunits.

Regulation by proteolysis: energy-dependent proteases and their targets

A number of critical regulatory proteins in both prokaryotic and eukaryotic cells are subject to rapid, energy-dependent proteolysis. Rapid degradation combined with control over biosynthesis provides a mechanism by which the availability of a protein can be limited both temporally and spatially. Highly unstable regulatory proteins are involved in numerous biological functions, particularly at the commitment steps in developmental pathways and in emergency responses. The proteases involved in energy-dependent proteolysis are large proteins with the ability to use ATP to scan for appropriate targets and degrade complete proteins in a processive manner. These cytoplasmic proteases are also able to degrade many abnormal proteins in the cell.

Role of the rfaG and rfaP genes in determining the lipopolysaccharide core structure and cell surface properties of Escherichia coli K-12

Deletions which removed rfa genes involved in lipopolysaccharide (LPS) core synthesis were constructed in vitro and inserted into the chromosome by linear transformation. The deletion delta rfa1, which removed rfaGPBI, resulted in a truncated LPS core containing two heptose residues but no hexose and a deep rought phenotype including decreased expression of major outer membrane proteins, hypersensitivity to novobiocin, and resistance to phage U3. In addition, delta rfa1 resulted in the loss of flagella and pili and a mucoid colony morphology. Measurement of the synthesis of beta-galactosidase from a cps-lacZ fusion showed that the mucoid phenotype was due to rcsC-dependent induction of colanic acid capsular polysaccharide synthesis. Complementation of delta rfa1 with rfaG+ DNA fragments resulted in a larger core and restored the synthesis of flagella and pili but did not reverse the deep rough phenotype or the induction of cps-lacZ, while complementation with a fragment carrying only rfaP+ reversed the deep rough phenotype but not the loss of flagella and pili. A longer deletion which removed rfaQGPBIJ was also constructed, and complementation studies with this deletion showed that the product of rfaQ was not required for the functions of rfaG and rfaP. Thus, the function of rfaQ remains unknown. Tandem mass spectrometric analysis of LPS core oligosaccharides from complemented delta rfa1 strains indicated that rfaP+ was necessary for the addition of either phosphoryl (P) or pyrophosphorylethanolamine (PPEA) substituents to the heptose I residue, as well as for the partial branch substitution of heptose II by heptose III. The substitution of heptose II is independent of the type of P substituent present on heptose I, and this results in four different core structures. A model is presented which relates the deep rough phenotype to the loss of heptose-linked P and PPEA.

A simple approach for the distribution of computationally intense tasks in an heterogeneous environment: distribution of the MDPP image-processing package

A method has been developed to link the display ability of a high-resolution graphics workstation with the computational power of a local mainframe or a remote supercomputer via an electronic data network. The method allows this link to be established in a manner largely transparent to the user. The application of the method is illustrated by our successful distribution of the computationally intensive portions of an imaging program (MDPP) from a small VAX workstation to a VAX mainframe and Cray Y-MP8/832 using a simple message-passing technique. This technique can be applied to almost any configuration of networked machines.

Regulation of capsular polysaccharide synthesis in Escherichia coli K12

Synthesis of the capsular polysaccharide colanic acid in Escherichia coli K12 is regulated by a complex network of regulatory proteins. This regulation is expressed at the level of transcription of the cps (capsular polysaccharide synthesis) genes. Two positive regulators, RcsA and RcsB, are necessary for maximal capsule expression. The availability of RcsA is normally limited because the RcsA protein is rapidly degraded by the Lon ATP-dependent protease. Therefore Lon acts, indirectly, as a negative regulator of capsule synthesis. The sequence predicted for RcsB suggests that it is the effector component of a two-component system; a protein with homology to sensors, RcsC, also plays a role in capsule regulation. We propose a model for capsule synthesis in which RcsA interacts with RcsB to stimulate transcription of the cps genes. The mechanism of regulation of colanic acid synthesis in E. coli may apply to other capsules in a variety of Gram-negative bacteria.

Characterization of Escherichia coli mutants with altered ploidy

We describe the isolation and characterization of new mutants in the cell cycle of Escherichia coli. The mutants were selected as gain of function mutants that are able to maintain more than the normal number of chromosomes. Our increased ploidy mutants were isolated as resistant to camphor vapours, which selects for cells with more chromosomes than normal. The mutants (called mbr for moth-ball-resistant) map to four chromosomal locations: mbrA at 68 min; mbrB at 88.5 min; mbrC at 89.5 min; and mbrD at 90 min. To investigate the nature of these cell cycle mutants, we have coupled them with defects in recA, to test for induction of the SOS response, and dam, to determine if methylation is required for mbr function. Based on the results of these and other tests, we have made a preliminary placement of the mbr mutants within the context of the cell cycle. mbrA mutations appear to be defective in the coupling of the DNA replication cycle to the cell division cycle, and as such, may define a new link between the two processes. mbrB does not seem to be able to coordinate the cell cycle and the growth rate of the cell. mbrC appears to be defective in partitioning of chromosomes. mbrD, which may be allelic to rpoB (a subunit of RNA polymerase), appears to be defective in either chromosomal partitioning or the later stages of DNA replication.

A mechanism for maintaining an up-to-date GenBank database via Usenet

In this paper, we describe an automated system for distributing updates to the GenBank nucleic acid sequence database, using the Usenet news system as the underlying transport mechanism. Our system allows new loci to be distributed as soon as the sequences are available, over existing networks, using existing Usenet software and infrastructure currently available on a wide range of computer systems.

On the bacterial cell cycle: Escherichia coli mutants with altered ploidy

We describe a scheme for isolation of new classes of mutants in the cell cycle of Escherichia coli. The mutants were selected as resistant to camphor vapors, which results in increased ploidy, and were subsequently screened for an increase in cell density and an increase in the gene dosage of the lac operon. Our mutations are located at four different places in the chromosome; we have named these loci mbr (moth ball resistant). mbrA maps to 68 min on the E. coli chromosome, mbrB to 88.5 min, mbrC to 89.5 min, and mbrD to 90 min. mbrD mutations may be alleles of rpoB (a subunit of RNA polymerase). In addition to the selected or screened phenotypes, most of the mutants fail to grow on rich media or at high temperatures. We have examined the nine mutants under nonpermissive conditions, using several techniques to determine the cause of death. We have also coupled our mutations with lesions in dnaA, which is required for cell-cycle-specific DNA replication, and rnh (the gene for RNase H), which is required for specificity in the DNA initiation reaction, and determined the effects of the double and triple mutants under permissive and nonpermissive conditions. These tests have shown that bacteria mutated at mbrA do not tolerate a null mutation in rnh, indicating that they are dependent on DNA replication initiating at oriC. In contrast, mutations at mbrB, mbrC, and mbrD exhibit their phenotypes independent of oriC initiation of DNA replication, suggesting that the mutations affect factors that influence the DNA/cell ratio regardless of the origin of DNA replication. Based on our results, the mbr mutations appear to have defects in cell-cycle timing and/or defects in chromosomal partitioning.

Clp P represents a unique family of serine proteases

The amino acid sequence of Clp P, the proteolytic subunit of the ATP-dependent Clp protease of Escherichia coli, closely resembles a protein encoded by chloroplast DNA, which is well conserved between chloroplasts of different plant species. The homology extends over almost the full length of the sequences of both proteins and consists of approximately 46% identical and approximately 70% similar amino acids. Antibodies against E. coli Clp P cross-reacted with proteins with Mr of 20,000-30,000 in bacteria, lower eukaryotes, plants, and animal cells. Since the regulatory subunit of Clp protease, Clp A, also has a homolog in plants, as well as in other bacteria and in lower eukaryotes, it is likely that ATP-dependent proteolysis in chloroplasts is catalyzed in part by a Clp-like protease and that both components of Clp-like proteases are widespread in living cells. We have identified Ser-111 as the active site serine in E. coli Clp P modified by diisopropyl fluorophosphate. Mutational alteration of Ser-111 or His-136 eliminates proteolytic activity of Clp P. Both residues are found in highly conserved regions of the protein. The sequences around the active site residues suggest that Clp P represents a unique class of serine protease. Amino-terminal processing of cloned Clp P mutated at either Ser-111 or His-136 occurs efficiently when wild-type clpP is present in the chromosome but is blocked in clpP- hosts. Processing of Clp P appears, therefore, to involve an intermolecular autocatalytic cleavage reaction. Since processing of Clp P occurs in clpA- cells, the autoprocessing activity of Clp P is independent of Clp A.

Sequence and structure of Clp P, the proteolytic component of the ATP-dependent Clp protease of Escherichia coli

The ATP-dependent Clp protease of Escherichia coli contains two dissimilar components: the Clp A regulatory polypeptide, with two ATP binding sites and intrinsic ATPase activity, and the Clp P subunit, which contains the proteolytic active site. The DNA sequence of the clpP gene predicts a protein of 207 amino acids (Mr 21,679), which is in close agreement with the size determined by sodium dodecyl sulfate-gel electrophoresis of purified Clp P. Clp P has a native Mr of approximately 240,000, and electron micrographs of the protein show superimposed disk-like structures with a central cavity, similar in appearance to purified proteasomes from eukaryotic cells. Clp P is synthesized with a 14-amino acid leader which is rapidly cleaved in vivo to yield the 193-amino acid protein which has activity in vitro. The clpP gene is at 10 min on the E. coli map, close to that for the ATP-dependent Lon protease of E. coli and far from the gene for clpA. Primer extension experiments indicate that transcription initiates immediately upstream of the coding region for Clp P, with a major transcription start at 120 bases in front of the start of translation. Insertion mutations in clpP have been isolated and transferred to the chromosome; strains devoid of Clp P are viable in the presence or absence of Lon protease. Mutations in clpP stabilize the same Clp A-beta-galactosidase fusion protein specifically stabilized by clpA mutations, providing the first genetic evidence that Clp A and Clp P act together in vivo.