The H3 chaperone function of NASP is conserved in Arabidopsis

Histones are abundant cellular proteins but, if not incorporated into chromatin, they are usually bound by histone chaperones. Here, we identify Arabidopsis NASP as a chaperone for histones H3.1 and H3.3. NASP interacts in vitro with monomeric H3.1 and H3.3 as well as with histone H3.1–H4 and H3.3–H4 dimers. However, NASP does not bind to monomeric H4. NASP shifts the equilibrium between histone dimers and tetramers towards tetramers but does not interact with tetramers in vitro. Arabidopsis NASP promotes [H3–H4]₂ tetrasome formation, possibly by providing preassembled histone tetramers. However, NASP does not promote disassembly of in vitro preassembled tetrasomes. In contrast to its mammalian homolog, Arabidopsis NASP is a predominantly nuclear protein. In vivo, NASP binds mainly monomeric H3.1 and H3.3. Pulldown experiments indicated that NASP may also interact with the histone chaperone MSI1 and a HSC70 heat shock protein.     

Change of cytochrome c structure during development of the mouse.

The structure of cytochrome c during mouse development is investigated. For this purpose the amino acid sequence of cytochrome c of the adult mouse had to be determined. The structure of cytochrome c of adult differentiated mouse cells differs in two amino acid residues from the known amino acid sequence of rabbit cytochrome c. No indication of different forms of cytochrome c in the adult differentiated cells was obtained. The structure of cytochrome c from 11.5-day-old mouse embryos is identical with that of adult mouse tissues. Since germ cells after meiotic division are the immediate precursors of a new individual, the structure of cytochrome c from sperm-containing mice testes was investigated. By means of chromatography of the cytochrome c and of peptide maps and amino acid analyses of its tryptic peptides, it is shown that mouse testis contains two isocytochromes c in about equal amount. The structure of one of these two isocytochromes c is identical with the structure of the adult-type cytochrome c of mouse. The testis-specific cytochrome c, which is assumed to be located in the sperm cells, differs in 13 of its 104 amino acid residues from the adult-type cytochrome c. From comparison of the primary and the spatial structures of the adult-type and the sperm-type isocytochromes c with the known structures of cytochrome c of more than 65 different species it is concluded that the duplication of the cytochrome c structural gene, causing the existence of the two ontogenetic-specific isocytochromes c in mouse, has occurred early in the evolution of eucaryotes.     

Chromatin organization in the male germ line of Drosophila hydei

The chromatin organization in developing germ cells of Drosophila hydei males was studied with the highly sensitive DNA stain DAPI (4, 6-diamidino-2-phenylindole dichloride). The prophase of meiosis I is characterized by decondensed chromosomes and only late during this stage do they condense rapidly. The sex chromosomes show allocycly. During postmeiotic development the final condensation of chromatin is preceded by a cycle of condensation and subsequent decondensation. Meiotic chromosomes were studied in more detail after orcein staining. Pairing sites of the sex chromosomes could be localized in the distal end of the heterochromatic arm of the X chromosome and distally in both arms of the Y chromosome. The various heterochromatic parts of the genome condense differentially in meiosis. Chromatin reorganization was studied cytochemically with antibodies raised against histones H1 and H2A of D. melanogaster. The core histone H2A is present in spermatid nuclei until the late elongation stage. However, histone H1 is not found in the chromatin later than the early primary spermatocyte stage. Thus, chromatin reorganization during spermatogenesis in D. hydei is complex. The process is discussed with regard to possible functions.     

Rapid and high resolution detection of in situ hybridisation to polytene chromosomes using fluorochrome-labeled RNA

Fluorochrome-labeled RNA allows the rapid detection of in situ hybrids without the need for long exposure times as in the autoradiographical hybridisation methods. Resolution is high because of the high resolving power of fluorescence microscopy. The application of a previously reported method for the hybrido-cytochemical detection of DNA sequences to polytene chromosomes of Drosophilia is described. — The specificity and sensitivity of the method are demonstrated by the hybridisation with polytene chromosomes of 1) rhodamine-labeled 5S RNA, to the 5S rRNA sites of D. melanogaster (56F) and D. hydei (23 B), 2) rhodamine-labeled RNA complementary to a plasmid containing histone genes, to the 39DE region of D. melanogaster, 3) rhodamine-labeled D. melanogaster tRNA species (Gly-3 and Arg-2), to their respective loci in D. melanogaster, 4) rhodamine-labeled RNA complementary to the insert of plasmid 232.1 containing part of a D. melanogaster heat shock gene from locus 87 C, to D. hydei heat shock locus 2-32A. In the latter instance it was possible to demonstrate the labeling of a double band which escaped unambiguous detection by autoradiography in the radioactive cytochemical hybridisation procedure because of the low topological resolution of autoradiograms. — The sensitivity of the fluorochrome-labeled RNA method is compared with the radioactive methods which use ³H- or ¹²⁵I-labeled RNAs. The factors governing the sensitivity and the number of bound fluorochrome molecules to be expected are discussed.Dedicated to Professor W. Beermann in honour of his 60th birthday     

Unusual clustering of diseases in a Canadian Old Colony (Chortitza) Mennonite kindred and community.

We investigated a large Old Colony (Chortitza) Mennonite kindred with branches across Canada. Six generations of the kindred were traced. There was intermarriage among numerous family members. Insulin-dependent diabetes mellitus (IDDM) was identified in 10 members; all 7 living patients were found to carry the immunogenetic marker HLA-DR4. Nine other close relatives had disorders of carbohydrate metabolism, including gestational diabetes mellitus and non-insulin-dependent diabetes mellitus progressing to insulin use. Ten other relatives had autoimmune diseases, including rheumatoid arthritis, hyperthyroidism, hypothyroidism and multiple sclerosis. Cases of Alport''s syndrome, congenital malformations, inborn errors of metabolism and unusual malignant diseases were also found in the kindred. In the small Alberta community in which the kindred was ascertained there were people of Old Colony Mennonite descent with genetic conditions such as Gilles de la Tourette''s syndrome and congenital malformations, including congenital heart disease. This kindred represents the largest reported familial aggregation of IDDM. This disease and other disorders of carbohydrate metabolism occur in the context of a strong familial predisposition to autoimmune disease. Study of this family may permit empiric testing of proposed models of inheritance of diseases of complex origin such as IDDM. We report this Old Colony (Chortitza) Mennonite community because it is one of the settlements populated by this religious and genetic isolate, which extends across Canada and Central and South America and affords opportunities for the study of both common and rare inherited diseases.     

Lipid peroxidation and endothelial cell injury: implications in atherosclerosis

Vascular endothelial cells, which play an active role in the physiological processes of vessel tone regulation and vascular permeability, form a border separating deeper layers of the blood vessel wall and cellular interstitial space from the blood and circulating cells. Damage or dysfunction of endothelial cells may reduce the effectiveness of the endothelium to act as a selectively permeable barrier to plasma components, including cholesterol-rich lipoprotein remnants. This may be involved in the etiology of atherosclerosis. Experimental evidence indicates that free radical-mediated lipid peroxidation can induce endothelial cell injury/dysfunction. Reactive oxygen species, including peroxidized lipids capable of initiating cell injury, may be generated within endothelial cells, be present in plasma components, or be derived from neutrophils or other blood-borne cells. Lipid peroxidation could initiate or promote the process of atherosclerotic lesion formation by directly damaging endothelial cells, and by enhancing the adhesion and activation of neutrophils and the susceptibility of platelets to aggregate. Endothelial cell injury by lipid hydroperoxides also could increase the uptake of LDL into the vessel wall. These events and other cellular dysfunctions may individually or collectively initiate and/or help to sustain the development of atherosclerosis.