Molecular characterization and distribution of CYCLE protein from Athalia rosae

Characterizing the relative abundance of circadian transcription factors in diapausing and nondiapausing Northern house mosquitoes

The Northern house mosquito (Culex pipiens) is a major vector of West Nile virus. To survive harsh conditions in winter adult females of Cx. pipiens enter a state of arrested reproductive development called diapause. Diapause is triggered by the short daylengths of late summer and early fall. The methods by which Cx. pipiens measures daylength are still unknown. However, it is suspected that clock genes, which provide information on daylength, may also regulate diapause. The proteins produced by these genes often cycle in abundance throughout the day in diapausing and nondiapausing insects. Two clock genes suspected to control diapause are cycle (cyc) and Par domain protein1 (Pdp1) as they encode circadian transcription factors that may regulate genes that are involved in diapause. Using Western blotting we measured the relative protein abundance of CYC and PDP1 throughout the day in the whole bodies and the heads of Cx. pipiens reared under either long-day, diapause-averting conditions or short-day, diapause-inducing conditions. We found that in whole bodies there was no significant oscillation of CYC or PDP1 abundance in both long day and short day-reared mosquitoes. In the heads of long day-reared mosquitoes both CYC and PDP1 cycled. In contrast, only PDP1 abundance showed diel differences in abundance in the heads of short day-reared mosquitoes. These data bring us one step closer to understanding the role that CYC and PDP1 may play in regulating diapause and other biological processes.

The expression of the clock gene cycle has rhythmic pattern and is affected by photoperiod in the moth Sesamia nonagrioides

To obtain clues to the link between the molecular mechanism of circadian and photoperiod clocks, we have cloned the circadian clock gene cycle (Sncyc) in the corn stalk borer, Sesamia nonagrioides, which undergoes facultative diapause controlled by photoperiod. Sequence analysis revealed a high degree of conservation among insects for this gene. SnCYC consists of 667 amino acids and structural analysis showed that it contains a BCTR domain in its C-terminal in addition to the common domains found in Drosophila CYC, i.e. bHLH, PAS-A, PAS-B domains. The results revealed that the sequence of Sncyc showed a similarity to that of its mammalian orthologue, Bmal1. We also investigated the expression patterns of Sncyc in the brain of larvae growing under long-day 16L: 8D (LD), constant darkness (DD) and short-day 10L: 14D (SD) conditions using qRT-PCR assays. The mRNAs of Sncyc expression was rhythmic in LD, DD and SD cycles. Also, it is remarkable that the photoperiodic conditions affect the expression patterns and/or amplitudes of circadian clock gene Sncyc. This gene is associated with diapause in S. nonagrioides, because under SD (diapause conditions) the photoperiodic signal altered mRNA accumulation. Sequence and expression analysis of cyc in S. nonagrioides shows interesting differences compared to Drosophila where this gene does not oscillate or change in expression patterns in response to photoperiod, suggesting that this species is an interesting new model to study the molecular control of insect circadian and photoperiodic clocks.

Expanding the view of Clock and cycle gene evolution in Diptera

We expanded the view of Clock (Clk) and cycle (cyc) gene evolution in Diptera by studying the fruit fly Anastrepha fraterculus (Afra), a Brachycera. Despite the high conservation of clock genes amongst insect groups, striking structural and functional differences of some clocks have appeared throughout evolution. Clk and cyc nucleotide sequences and corresponding proteins were characterized, along with their mRNA expression data, to provide an evolutionary overview in the two major groups of Diptera: Lower Diptera and Higher Brachycera. We found that AfraCYC lacks the BMAL (Brain and muscle ARNT-like) C-terminus region (BCTR) domain and is constitutively expressed, suggesting that AfraCLK has the main transactivation function, which is corroborated by the presence of poly-Q repeats and an oscillatory pattern. Our analysis suggests that the loss of BCTR in CYC is not exclusive of drosophilids, as it also occurs in other Acalyptratae flies such as tephritids and drosophilids, however, but it is also present in some Calyptratae, such as Muscidae, Calliphoridae and Sarcophagidae. This indicates that BCTR is missing from CYC of all higher-level Brachycera and that it was lost during the evolution of Lower Brachycera. Thus, we can infer that CLK protein may play the main role in the CLK\CYC transcription complex in these flies, like in its Drosophila orthologues.

The clock gene cycle plays an important role in the circadian clock of the cricket Gryllus bimaculatus

To dissect the molecular oscillatory mechanism of the circadian clock in the cricket Gryllus bimaculatus, we have cloned a cDNA of the clock gene cycle (Gb'cyc) and analyzed its structure and function. Gb'cyc contains four functional domains, i.e. bHLH, PAS-A, PAS-B and BCTR domains, and is expressed rhythmically in light dark cycles, peaking at mid night. The RNA interference (RNAi) of Clock (Gb'Clk) and period (Gb'per) reduced the Gb'cyc mRNA levels and abolished the rhythmic expression, suggesting that the rhythmic expression of Gb'cyc is regulated by a mechanism including Gb'Clk and Gb'per. These features are more similar to those of mammalian orthologue of cyc (Bmal1) than those of Drosophila cyc. A single treatment with double-stranded RNA (dsRNA) of Gb'cyc effectively knocked down the Gb'cyc mRNA level and abolished its rhythmic expression. The cyc RNAi failed to disrupt the locomotor rhythm, but lengthened its free-running period in constant darkness (DD). It is thus likely that Gb'cyc is involved in the circadian clock machinery of the cricket. The cyc RNAi crickets showed a rhythmic expression of Gb'per and timeless (Gb'tim) in the optic lobe in DD, explaining the persistence of the locomotor rhythm. Surprisingly, cyc RNAi revealed a rhythmic expression of Gb'Clk in DD which is otherwise rather constitutively expressed in the optic lobe. These facts suggest that the cricket might have a unique clock oscillatory mechanism in which both Gb'cyc and Gb'Clk are rhythmically controlled and that under abundant expression of Gb'cyc the rhythmic expression of Gb'Clk may be concealed.

Molecular cloning and functional analysis of the clock genes, Clock and cycle, in the firebrat Thermobia domestica

Comparative molecular analysis reveals a wide variation of clock mechanisms among insects. In this study, the clock gene homologues of Clock (Td'Clk) and cycle (Td'cyc) were cloned from an apterygote insect, Thermobia domestica. Structural analysis showed that Td'CLK includes bHLH, PAS-A, PAS-B domains but lacks a polyglutamine repeat in the C terminal region that is implicated for transcriptional activity in Drosophila CLK. Td'CYC contains a BCTR domain in its C terminal in addition to the common domains found in Drosophila CYC, i.e. bHLH, PAS-A, PAS-B domains. Unlike in Drosophila, Td'Clk mRNA levels showed no significant daily fluctuation, while Td'cyc exhibited rhythmic expression. A single injection of double-stranded RNA (dsRNA) of Td'Clk or Td'cyc into the abdomen of adult firebrats effectively knocked down respective mRNA levels and abolished the rhythmic expression of Td'cyc. Most Td'Clk or Td'cyc dsRNA-injected firebrats lost their circadian locomotor rhythm in constant darkness up to 30 days after injection, whereas those injected with DsRed2 dsRNA as a negative control clearly maintained it. From these results, it is likely that Td'Clk and Td'cyc are involved in the circadian clock machinery in the firebrat. However, the structure and expression profile of Td'Clk and Td'cyc more closely resembles those of mammals than Drosophila.

RNA interference of the clock gene period disrupts circadian rhythms in the cricket Gryllus bimaculatus

Periodic expression of so-called clock genes is an essential part of the circadian clock. In Drosophila melanogaster the cyclic expression of per and tim through an autoregulatory feedback loop is believed to play a central role in circadian rhythm generation. However, it is still elusive whether this hypothesis is applicable to other insect species. Here it is shown that per gene plays a key role in the rhythm generation in the cricket Gryllus bimaculatus. Measurement of per mRNA levels in the optic lobe revealed the rhythmic expression of per in light cycles with a peak in the late day to early night, persisting in constant darkness. A single injection of per double-stranded RNA (dsRNA) into the abdomen of the final instar nymphs effectively knocked down the mRNA levels as adult to about 50% of control animals. Most of the per dsRNA-injected crickets completely lost the circadian locomotor activity rhythm in constant darkness up to 50 days after the injection, whereas those injected with DsRed2 dsRNA as a negative control clearly maintained it. The electrical activity of optic lobe efferents also became arrhythmic in the per dsRNA-injected crickets. These results not only suggest that per plays an important role in the circadian rhythm generation also in the cricket but also show that RNA interference is a powerful tool to dissect the molecular machinery of the cricket circadian clock.

Molecular characterization of the circadian clock genes in the bean bug, Riptortus pedestris, and their expression patterns under long- and short-day conditions

Although the molecular mechanisms and the diversity of insect circadian clocks have been well investigated in holometabolous insects, hemimetabolous insects have received little attention. In the present study, we isolated the circadian clock genes, period (per), cycle (cyc), vrille (vri), and mammalian-type cryptochrome (cry-m) from the bean bug Riptortus pedestris. This is the first report of vri and cry-m in hemimetabolous insects. All of the genes showed high similarities to respective homologous genes in other insects. The discovery of cry-m in R. pedestris indicates that the clockwork of hemimetabolous insects is similar to that in insects having CRY-m, including the monarch butterfly Danaus plexippus and the honey bee Apis mellifera, and not to insects lacking it, such as Drosophila melanogaster. Real-time PCR showed that mRNAs of these circadian clock genes exhibited extremely weak diel oscillations at day 9 in the head of R. pedestris, and their expression levels under long- and short-day conditions were nearly identical. In addition, expression levels of per mRNA were almost stable from days 0 to 15 under both photoperiodic conditions. The difference between long-day and short-day conditions in the mRNA level seems too small to distinguish photoperiodic conditions clearly. These results suggest that transcriptional regulations of circadian clock genes would not play an important role in the diapause programming in R. pedestris.

Molecular structure, expression patterns, and localization of the circadian transcription modulator CYCLE in the cricket, Dianemobius nigrofasciatus

CYCLE (CYC), also known as BMAL1 in vertebrate nomenclature, is a transcription modulator of the circadian genes period and timeless of Drosophila melanogaster. We cloned a cDNA encoding a CYC homologue from the head of the ground cricket, Dianemobius nigrofasciatus (Dncyc), the first CYC from Hemimetabola. The deduced sequence corresponded to a 601 amino-acid polypeptide, with well-defined bHLH, PAS-A, PAS-B, PAC, and BTCR domains. The amino-acid sequence showed 70.7% identity with the CYC protein of Athalia rosae, 63.8% with D. melanogaster, and 52% identity with the human homologue. A cyc transcript of around 3.6kb occurs in the brain, midgut, testis, fatbody, and muscle. An additional band of around 1.1kb gave a hybridization signal in the head. No temporal oscillation in cyc mRNA abundance was observed in the head of the adult cricket when investigated by Northern blot analysis. CYC-like immunohistochemical reactivity (ir) and its dimerization partner CLOCK (CLK)-ir appeared in the pars intercerebralis (PI), tritocerebrum, dorsolateral protocerebrum, and subesophageal ganglion (SOG), but no CYC-ir was observed in the optic lobe (OL) that showed CLK-ir. The deutocerebrum showed a unique CLK-ir but no CYC-ir pattern. Double-labelling experiments showed that both antigens were co-localized in the mandibular and maxillary neuromeres of the SOG. CYC-ir showed no daily oscillation in intensity and the staining pattern was always cytoplasmic. CLK-ir occurred in the nucleus at ZT 16, but was cytoplasmic at other ZT times. A neuronal network equivalent to adult system occurred in the second nymphal stadium.