Evidence for a low-molecular-weight collagen precursor.

In this communication evidence is presented that collagen-proline hydroxylation occurs on polypeptides of low molecular weight. Thus, the hydroxylation process is initiated prior to the completion of the synthesis of collagen α-chains. The present data rule out the participation of any proteolytic enzymes in obtaining low-molecular-weight polypeptides containing hydroxyproline

DNA-binding activity of tightly-bound nonhistone chromosomal proteins in chicken liver chromatin.

We have isolated a nonhistone chromosomal protein fraction from chicken liver chromatin which possesses high affinity and preferential sequence DNA binding. Residually DNA-bound nonhistone chromosomal proteins after 2.0 M NaCl extraction of bulk chromatin are isolated. Bound proteins are released by dissociation of the complexes in 5.0 M urea/3.0 M NaCl. We have investigated the in vitro DNA-binding properties of this class. In contrast to other DNA-binding NHCP whose activities have been studied, direct DNA-binding activity is observed which is not abolished under conditions of high ionic strength (to 3.0 M NaCl). Strong preference in binding fractionated homologous DNA is observed, while binding of heterologous (E. Coli) DNA is negligible. The fractionation of homologous DNA permits the isolation of DNA for which this protein class displays strong binding preference, presumably through a concentration of binding sites. The composite data suggest sequence-specific interaction between this protein class and DNA, which is not abolished by high ionic strength

DNA sequence selection by tightly-bound nonhistone chromosomal proteins.

Extraction of chicken reticulocyte chromatin with 2.0 M NaCl removed 96% of chromosomal protein and yields two DNA components after dialysis and high-speed centrifugation. The bulk of chromosomal DNA (ca. 99%) is rendered free of protein, and is thus soluble in 10 mM Tris-HCl, pH 8.0. The other component (ca. 1%) displays a high protein/DNA ratio, and is insoluble in 10mM Tris-HCl, pH 8.0. These DNAs can be separated on the basis of their solubilities. Analysis of the reassociation kinetics with total chicken DNA of these DNAs reveals marked differences. Whereas total DNA and the soluble component (DNA-S) have rapidly reassociating components, the insoluble component (DNA-P) is devoid of these components, and is therefore composed completely of unique sequence DNA. Cot 1/2 values indicate that DNA-S is substantially depleted of some DNA-P sequences. We conclude that this segregation, as determined by tightly-bound nonhistone chromosomal proteins, selects a subset of total genomic DNA sequences, and suggests sequence-specific interaction between the tightly-bound nonhistones and DNA