Investigations on chromatin condensation of hen erythrocyte nuclei in vitro. An ultrastructural and biochemical study

Histone cross-linking by transglutaminase

Transglutaminases irreversibly catalyze covalent cross-linking of proteins by forming isopeptide bonds between peptide-bound glutamine and lysine residues. Among several transglutaminases, tissue-type transglutaminase (tTGase) is most ubiquitously found in every type of cells and tissues in animals, but its natural substrate has yet to be identified. In an attempt to identify the natural substrate for tTGase, we examined in vitro if core histones were subject to cross-linking by tTGase. We found core histone subunits, H2A and H2B, were specifically cross-linked by tTGase. The cross-linking was between either one or both glutamines at C-terminal end of H2A (-VTIAQ104 GGVLPNTQ112 SVLLPKKTESSKSK-C' end) and the first and/or third lysine from C-terminal end of H2B (-AVESEGK116 AVTKYTSSK125-C' end). The cross-linking occurred only when these subunits were released from nucleosome but not when these were organized in nucleosome. Most interestingly, in chicken erythrocyte the cross-linked H2A-H2B was present in a significant amount. From these results, it can be proposed that tTGase-mediated cross-linking is an another form of core histone modification and it may play a role of chromatin condensation during erythrocyte differentiation.

Chromatin structure in granulocytes. A link between tight compaction and accumulation of a heterochromatin-associated protein (MENT)

To study the mechanism of heterochromatin formation in vertebrate cells, we isolated nuclei from chicken polymorphonuclear granulocytes and examined the chromatin organization. We found granulocyte chromatin to remain insoluble after nuclease digestion and to be resistant to swelling in low salt/high pH media. Both insolubility and resistance to swelling were lost after washing with 0.3 M NaCl, a procedure that released two abundant tissue-specific proteins from granulocyte nuclei. One of them (42 kDa) is identified as MENT, a protein previously shown to be associated with repressed chromatin from mature chicken erythrocytes. We show that MENT is immunolocalized in granulocyte heterochromatin, where it is one of the most abundant chromatin proteins ( approximately 2 molecules/200 base pairs of DNA). MENT is the first nuclear protein structurally related to the serine protease inhibitor family. The other abundant protein is similar to or identical with mim-1, a myeloid-specific protein that is known to be stored in cell granules and to associate with isolated nuclei. MENT (but not mim-1) binds chromatin and free DNA, and, at its physiological protein/DNA ratio, enhances compaction and the reversible Mg2+-dependent self-association of nucleosome arrays. MENT appears to promote the formation of heterochromatin by acting as a "glue" within and between chains of nucleosomes.

A novel nonhistone protein (MENT) promotes nuclear collapse at the terminal stage of avian erythropoiesis

The terminal stage of differentiation of nucleated chicken erythrocytes is associated with an overall gene repression and a condensation of the repressed chromatin portion. Two-dimensional DNP electrophoresis has been used to separate transcriptionally active and repressed chromatin of mature chicken erythrocytes. The repressed chromatin fraction is shown to be enriched with histone H5 as well as with a 42-kDa nonhistone chromosomal protein. The 42-kDa protein designated here as MENT (mature erythrocyte nuclear termination stage-specific protein) is hyperexpressed at the terminal stage of chicken erythropoiesis and is accumulated in adult chicken erythrocyte nuclei. This protein was purified by ion-exchange chromatography from 0.4 M NaCl extracts of the erythrocyte nuclei. It appeared to be a basic polypeptide (pI 9.2) which, however, precipitated at low pH. When reconstituted in vitro with immature erythrocyte nuclei, MENT promoted condensation of intact nuclear chromatin and enhanced the solubilization of nuclease-digested polynucleosomes, thus mimicking the processes occurring in vivo at the final stage of erythrocyte maturation. The extent of dissociation of specific gene sequences from the nuclear matrix in MENT-treated nuclei is in striking correlation with their transcriptional activity. No other basic proteins (H5, cytochrome c, RNase A) added to the nuclear preparation at the same level as MENT (protein/DNA = 0.005) caused any effect on nuclear organization. No alterations were observed when MENT was mixed with erythroblasts and nonerythroid nuclei having little or no histone H5. We propose that MENT cooperates with histone H5 to complete the nuclear collapse in mature nucleated erythrocytes.

Immunofluorescent study of histone H5 in chick erythroid cells from developing embryos and adults

Indirect immunofluorescence has been used to detect the presence of histone H5 in single cells during avian erythropoiesis. Evidence is presented which demonstrates that this method specifically detects histone H5. The results show that the increase in the amount of H5 which can be extracted from nuclei during erythropoiesis is accounted for both by an increase in the amount of H5 per cell and by an increase in the total number of cells containing histone H5. Of particular interest are the observations that histone H5 is arranged within the nucleus in several distinct, reproducible patterns and that different patterns predominate at different stages of erythroid cell development. In addition to suggesting new possibilities for the role of histone H5, these findings indicate that immunofluorescence may be used profitably to explore the supramolecular organization of chromatin.