Nuclease, micrococcal

Hydrolysis of RNA by alkali or pancreatic RNase leads initially to fragments which terminate in 2, 3 -cyclic phosphodiesters. Micrococcal nuclease, on the other hand, gives rise to fragments terminating in 3 -phos-phomonoester groups which facilitate their isolation, and this enzymic hydrolysis has been used to prepare 3 -ribodinucleotides. ... 

Fig. 8. Schematic for the micrococcal nuclease attack to (a) breathing ds-DNA, (b) dista-mycin-bound DNA, and (c) Zn2+-cyclen derivative-bound DNA. Arrows and dashed arrows, respectively, indicate successful and failed enzyme hydrolysis. Reproduced with permission from Ref. (37). Copyright 1999, American Chemical Society.

The histone core protects the DNA bound to the nucleosome from digestion by pan-creatic deoxyribonuclease (DNase) I or micrococcal nuclease. Nucleases, however, will cleave the linker DNA that connects the nucleosome subunits to one another. 

The nucleosome is composed of 200 base pairs of DNA and an octamer of the histones H2A, H2B, H3, and H4 as well as histone HI (Komberg, 1974, 1977). Nucleosomes can be obtained by mild digestion of chromatin with micrococcal nuclease (Noll, 1974a Axel, 1975), followed by fractionation on a sucrose gradient. Further digestion of the nucleosomes results in the formation of nucleosome core particles composed of 145 base pairs of DNA and an octamer of the histones H2A, H2B, H3, and H4 (Rill and Van Holde, 1973 Sollner-Webb and Felsenfeld, 1975 Axel, 1975 Bakayev et al., 1975 Whitlock and Simpson, 1976 Noll and Komberg, 1977). The DNA piece thus excised is called linker DNA which serves as a link... 

Similar results were obtained from reconstitution experiments with DNA and a non-cross-linked octamer (Thomas and Butler, 1978). Nucleosome-like particles were observed in the EM and a pattern of histone cross-linking comparable to that of native chromatin was obtained. However, only 140-base-pair repeats were obtained upon micrococcal nuclease digestion instead of 200-base-pair repeats obtained for native rat liver chromatin (Noll and Komberg, 1977). This indicates that, in the absence of HI, only core particles can be reconstituted. Nevertheless, these studies with both cross-linked and reassembled un-cross-linked histones demonstrate that the octamer is a complete biological functional unit retaining the information for folding the DNA around the histone core. 

Nucleosomes core particles containing H2A only have 118 base pairs of DNA incorporated compared to the canonical nucleosomes protecting about 147 base pairs from micrococcal nuclease (Bao et al. 2004). These nucleosomes are more flexible in structure and might facilitate passage of RNA polymerase II. However, the function of this histone variant in mammalian cells is not fully understood. As... 

Antibiotic Mg complex induced alteration in the ultrastructural changes in the native and HI depleted chromatin were monitored by thermal melting analysis, polyacrylamide gel mobility assay, dynamic light scattering experiments and transmission electron microscopic studies. Micrococcal nuclease digestion is the biochemical probe to assess the accessibility of the antibiotic Mg + complexes to nucleosomal DNA. 

Depletion of histone HI after covalent modification from chromatin is a key step in eukaryotic transcription (Lee et al, 1993 Juan et al, 1994 Rice and Allis, 2001). A comparison of the association of the antibiotic Mg + complexes with the normal and HI depleted chromatin suggests that smaller ligands, like anticancer drugs, have better accessibility for HI depleted chromatin compared to native chromatin. HI depleted chromatin is also more prone to aggregation upon association with the complex I of the antibiotic Mg + complexes. It is also less accessible to micrococcal nuclease. We propose that HI depleted chromatin is a better target of these antibiotics compared to native chromatin. This observation is particularly significant in case of neoplastic cells where most of the cell nuclei are transcriptionally active, and, therefore, contain HI depleted chromatin. 

The nucleosome is the fundamental repeating structural unit of chromatin. It is composed of two molecules of the core histones H2A, H2B, H3, H4, approximately two superhelical turns of double-stranded DNA, and linker histone HI (H5). In addition to biochemical studies, the existence of the nucleosome was established in electron micrographs (Fig. la) [1,2], and the name nucleosome, coined to incorporate the concept of the spherical nu-bodies [3]. Micrococcal nuclease limit digestion of chromatin established the nucleosome core particle (NCP) as the portion of the nucleosome containing only the core histones surrounded by 1.75 superhelical turns of double-stranded DNA [4,5]. 

Several lines of evidence indicate that CENP-A replaces conventional H3 in the nucleosome. Biochemical studies showed that CENP-A co-sediments with nucleo-some core particles [7] and a genetic analysis indicates an interaction between Cse4p, the CENP-A of Saccharomyces cerevisiae, and H4 [16,17]. A recent study with CENP-A purified from HeLa cells or expressed in bacteria showed that it can substitute for conventional H3 in nucleosome reconstitution [18]. Reconstituted CENP-A-containing nucleosomes appear to contain the other core histones in appropriate stoichiometry. However, they did not strongly protect 146 bp of core DNA from micrococcal nuclease, suggesting that CENP-A may significantly alter some aspects of the core nucleosome structure. 

Wood, W.I. and Felsenfeld, G. (1982) Chromatin structure of the chicken beta-globin gene region. Sensitivity to DNase I, micrococcal nuclease, and DNase II. J. Biol. Chem. 10 257(13), 7730-7736. 

It is obvious that the single-molecule approaches can reveal features of the dynamics of chromatin assembly and its force dependence that could not be observed using the standard biochemical assays to study assembly following changes in superhelicity in closed circular DNA molecules, looking at changes in protection against enzymes like micrococcal nuclease, or the accessibility of restriction enzymes. 

One of the very early research tools that were used to study the nucleosomal state of active genes were the nucleases, DNase I and Micrococcal nuclease. With the development of protocols for the isolation of nuclei from cells, it was possible to add these reagents to probe the accessibility of DNA. DNase I makes single nicks in double stranded DNA and when the DNA is associated with histones within the nucleosome, the DNA is extensively protected. Those nicks that are observed are found to occur only after extensive digestion and are limited to the outside surface of the DNA in 10 base increments [7,8]. Weintraub and Groudine in 1976 [9] first used this nuclease and observed that when nuclei from chicken erythrocytes were treated with DNase I, the active /1-globin gene was preferentially... 

Before the immunopreciptation step the chromatin has to be fragmented in order to make interactions accessible and to increase the resolution of the ChIP. Two different methods are commonly used fragmentation via sonication of the chromatin, or an enzymatic digestion with micrococcal nuclease. 

This hydrolase, officially known as micrococcal nuclease [EC 3.1.31.1 (formerly 3.1.4.7)], catalyzes endonucleolytic cleavage of single-Zdouble-stranded DNA (as well as RNA) to form 3 -phospho-mononucleotide and 3 -phospho-oligonucleotide end-products. The enzyme also displays exonucleolytic activity. 

Guisan, J.M. and Ballesteros, A. (1979) Preparation of immobiUzed sepharose-micrococcal nuclease derivatives aetivity and stability. J. Solid-Phase Biochem., 4, 245-252. 

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