Characterization of casein and alpha lactalbumin of African elephant (Loxodonta africana) milk.

The current research reports partial characterization of the caseins and α-lactalbumin (α-LA) of the African elephant with proposed unique structure-function properties. Extensive research has been carried out to understand the structure of the casein micelles. Crystallographic structure elucidation of caseins and casein micelles is not possible. Consequently, several models have been developed in an effort to describe the casein micelle, specifically of cow milk. Here we report the characterization of African elephant milk caseins. The κ-caseins and ß-caseins were investigated, and their relative ratio was found to be approximately 1:8.5, whereas α-caseins were not detected. The gene sequence of ß-casein in the NCBI database was revisited, and a different sequence in the N-terminal region is proposed. Amino acid sequence alignment and hydropathy plots showed that the κ-casein of African elephant milk is similar to that of other mammals, whereas the ß-casein is similar to the human protein, and displayed a section of unique AA composition and additional hydrophilic regions compared with bovine caseins. Elephant milk is destabilized by 62% alcohol, and it is speculated that the ß-casein characteristics may allow maintenance of the colloidal nature of the casein micelle, a role that was previously only associated with κ-casein. The oligosaccharide content of milk was reported to be low in dairy animals but high in some other species such as humans and elephants. In the milk of the African elephant, lactose and oligosaccharides both occur at high levels. These levels are typically related to the content of α-LA in the mammary gland and thus point to a specialized carbohydrate synthesis, where the whey protein α-LA plays a role. We report the characterization of African elephant α-LA. Homology modeling of the α-LA showed that it is structurally similar to crystal structures of other mammalian species, which in turn may be an indication that its functional properties, such as lactose synthesis, should not be impaired.

Over-expression and properties of a purified recombinant Bacillus licheniformis lipase: a comparative report on Bacillus lipases.

The gene coding for an extracellular lipase of Bacillus licheniformis was cloned using PCR techniques. The sequence corresponding to the mature lipase was subcloned into the pET 20b(+) expression vector to construct a recombinant lipase protein containing 6 histidine residues at the C-terminal. High-level expression of the lipase by Escherichia coli cells harbouring the lipase gene-containing expression vector was observed upon induction with IPTG at 30 degrees C. A one step purification of the recombinant lipase was achieved with Ni-NTA resin. The specific activity of the purified enzyme was 130 units/mg with p-nitrophenyl-palmitate as substrate. The enzyme showed maximum activity at pH 10-11.5 and was remarkably stable at alkaline pH values up to 12. The enzyme was active toward p-nitrophenyl esters of short to long chains fatty acids but with a marked preference for esters with C(6) and C(8) acyl groups. The amino acid sequence of the lipase shows striking similarities to lipases from Bacillus subtilis and Bacillus pumilus. Based on the amino acid identity and biochemical characteristics, we propose that Bacillus lipases be classified into two distinct subfamilies of their own.

DNAssist: the integrated editing and analysis of molecular biology sequences in windows.

MOTIVATION: The programs currently available for the analysis of nucleic acid and protein sequences suffer from a variety of problems: Web-based programs often require inconvenient reformatting of sequences when proceeding from one analysis to the next, and commercial-console-based programs are cost prohibitive. Here, we report the development of DNASSIST:, an inexpensive, multiple-document, interface program for the fully integrated editing and analysis of nucleic acid and protein sequences in the familiar environment of Microsoft Windows.

DNAssist, a C++ program for editing and analysis of nucleic acid and protein sequences on PC-compatible computers running Windows 95, 98, NT4.0 or 2000.

The size of sequence databases, the rapid rate of generating sequence data and the need to routinely construct recombinant DNA molecules in molecular biological research necessitate the frequent handling and analysis of nucleotide and protein sequences on a computer. Although several console or Web-based utility programs are available, the application of these programs generally requires reformatting the data when proceeding from one such program to the next. The acquisition of elaborate, integrated program suites is financially prohibitive to smaller laboratories. Here, we report the development of DNAssist, a shareware program for editing and analysis of nucleic acid and protein sequences. It was developed as a multiple-document interface program--similar to a word processor--where sequences are entered, edited and analyzed in a single integrated environment. DNAssist can calculate the physicochemical properties of a sequence, convert between nucleic acid and protein sequences, translate DNA in multiple frames, identify open reading frames and locate ambiguous sequence patterns allowing gaps and mismatches. DNAssist also performs restriction enzyme and transcription factor-binding site analyses of DNA sequences, the multiple alignment of nucleic acid and protein sequences and the analysis of DNA sequences for nucleosome positioning sites.

The biochemical and phenotypic characterization of Hho1p, the putative linker histone H1 of Saccharomyces cerevisiae.

There is currently no published report on the isolation and definitive identification of histone H1 in Saccharomyces cerevisiae. It was, however, recently shown that the yeast HHO1 gene codes for a predicted protein homologous to H1 of higher eukaryotes (Landsman, D. (1996) Trends Biochem. Sci. 21, 287-288; Ushinsky, S. C., Bussey, H. , Ahmed, A. A., Wang, Y., Friesen, J., Williams, B. A., and Storms, R. K. (1997) Yeast 13, 151-161), although there is no biochemical evidence that shows that Hho1p is, indeed, yeast histone H1. We showed that purified recombinant Hho1p (rHho1p) has electrophoretic and chromatographic properties similar to linker histones. The protein forms a stable ternary complex with a reconstituted core di-nucleosome in vitro at molar rHho1p:core ratios up to 1. Reconstitution of rHho1p with H1-stripped chromatin confers a kinetic pause at approximately 168 base pairs in the micrococcal nuclease digestion pattern of the chromatin. These results strongly suggest that Hho1p is a bona fide linker histone. We deleted the HHO1 gene and showed that the strain is viable and has no growth or mating defects. Hho1p is not required for telomeric silencing, basal transcriptional repression, or efficient sporulation. Unlike core histone mutations, a hho1Delta strain does not exhibit a Sin or Spt phenotype. The absence of Hho1p does not lead to a change in the nucleosome repeat length of bulk chromatin nor to differences in the in vivo micrococcal nuclease cleavage sites in individual genes as detected by primer extension mapping.

The translational placement of nucleosome cores in vitro determines the access of the transacting factor suGF1 to DNA.

The sea urchin G-string binding factor (suGF1) is one of several proteins that bind sequence-specifically to oligo(dGxdC) motifs, frequently present upstream of eukaryotic genes. In this study we investigate the interaction of suGF1, purified to near homogeneity, with its oligo(dGxdC) binding site in a reconstituted nucleosome core in vitro. We show that the in vitro reconstitution of a 214 bp fragment containing a suGF1 binding site results in the appearance of five distinct nucleosome core species. These species contain the histone octamer in an identical rotational setting but in different translational frames. The resulting different nucleosomal locations of the suGF1 binding site in the five core species are shown to modulate the ability of suGF1 to bind to nucleosomal DNA, even though the rotational setting of the DNA in the nucleosome cores maximally exposes the suGF1 binding site. We propose that a direct protein-protein steric clash between suGF1 and the histone octamer is the most likely determinant in modulating the binding of suGF1 to its nucleosomally wrapped binding site. This result suggests that in vivo suGF1, like TBP, NF1 and heat shock factor, may require a complementary nucleosome disrupting activity or that suGF1 binds to free nascent replicated DNA prior to nucleosome deposition.

Modified curved DNA that could allow local DNA underwinding at the nucleosomal pseudodyad fails to position a nucleosome in vivo.

In competitive in vitro reconstitution experiments synthetic DNA composed of tandem repeats of the repetitive sequence (A/T)3NN(G/C)3NN, specifically the 20 bp 'TG sequence' (5'-TCGGTGTTAGAGCCTGTAAC-3'), was reported to associate with the histone octamer with an affinity higher than that of nucleosomally derived DNA. However, at least two groups have independently shown that tandem repeats of the TG sequence do not accommodate a stably positioned nucleosome in vivo. It was suggested that the anisotropic flexibility of the TG sequence, governed by a 10 bp sequence periodicity, is incompatible with the required underwinding of the DNA helix at the nucleosome pseudodyad while maintaining a bending preference that can be accommodated in the remainder of the nucleosome. Here we test this hypothesis directly by studying the in vivo nucleosomal structure of modified TG sequences designed to accommodate underwinding at the pseudodyad. We show that these modifications are not sufficient to allow stable incorporation of the TG sequence repeat into a nucleosome in vivo, but do note invasion from one end of the TG heptamer of a translationally random but rotationally constrained nucleosome. We discuss possible reasons for the absence of nucleosomes from the TG sequence in vivo.

Nucleosomal location of the STE6 TATA box and Mat alpha 2p-mediated repression.

It has been proposed that yeast MATa cell-specific genes are repressed in MAT alpha cells by the Mat alpha 2p repressor-directed placement of a nucleosome in a position that incorporates the TATA box of the MATa-specific gene close to the nucleosomal pseudodyad. In this study, we address this proposal directly with a series of plasmids designed to place the MATa-specific STE6 TATA box at different locations in a nucleosome and in the internucleosomal linker. These plasmids contain different lengths of synthetic random DNA between the Mat alpha 2p operator and the TATA box of the STE6 promoter, which is located upstream of a lacZ reporter gene in a multicopy plasmid. We show that in MAT alpha cells, a nucleosome is retained in an identical translational frame relative to the Mat alpha 2p operator in all the constructs investigated, irrespective of the sequence of the DNA wrapped onto the histone octamer. This result shows that the nucleosomal organization of the STE6 promoter in MAT alpha cells is not conferred by the sequence of the promoter itself. No expression of the lacZ reporter gene was detectable in MAT alpha cells in any of the constructs, even with the TATA box located in a short internucleosomal linker. These data indicate that repression of MATa-specific genes in MAT alpha cells does not require the precise translational placement of the TATA box close to the nucleosomal pseudodyad; the gene remains repressed when the TATA box is located within the investigated 250-bp region in the organized chromatin domain abutting the Mat alpha 2p operator in MAT alpha cells and may remain repressed with the TATA box located anywhere within this organized repression domain.

Negative supercoiling and nucleosome cores. I. The effect of negative supercoiling on the efficiency of nucleosome core formation in vitro.

The efficiency of nucleosome core formation in vitro as a function of DNA topology was investigated. We show that the reconstitution of nucleosome cores by urea/salt dialysis on both negatively supercoiled and linearized plasmid proceed co-operatively, and that negatively supercoiled molecules are reconstituted significantly more efficiently compared with linearized molecules. The free energy of supercoiling, related to the square of the linking deficit, is further shown to be sufficient to account for this difference, which is particularly pronounced at low molar reconstitution ratios of octamer: DNA. At these low molar ratios the average number of cores formed per negatively supercoiled molecule is equal to the input ratio of octamer: DNA, in contrast to linearized molecules, where few if any cores are reconstituted under identical experimental conditions. The possible contribution of supercoil-stabilized non-B-DNA structural transitions to differences in core-DNA interactions on supercoiled and linearized DNA was also investigated. We show that the change in the nuclease susceptibility of a d(A-G).d(C-T) run in the free and reconstituted supercoiled plasmid is consistent with the reversion of the poly(purine).poly(pyrimidine) stretch from an H-DNA form to a B-DNA form following reconstitution of the negatively supercoiled plasmid into nucleosome cores. The biological significance of the supercoil-dependent efficiency of core formation is discussed, and the results related to other work.

Negative supercoiling and nucleosome cores. II. The effect of negative supercoiling on the positioning of nucleosome cores in vitro.

The influence of unrestrained negative superhelical stress on nucleosome core positioning was investigated in vitro for a core located on a section of the early H1-H4 histone gene spacer of Psammechinus miliaris. We show that the position of this core on a reconstituted molecule occupied by 11 nucleosome cores is identical on a linear DNA molecule and a circular DNA molecule in the absence of unrestrained negative superhelical stress. This position is also identical to that previously found on a 337 base-pair fragment of corresponding sequence. We conclude that the core position is determined primarily by the DNA sequence, and is not influenced by core-core interactions or spatial constraints imposed by an altered geometry of the DNA molecule. This finding is supported by the identical positions assumed by the nucleosome core after altering the angular orientation of the DNA molecule, and presumably that of adjacent cores, on either one or both sides of the test core. It is further demonstrated that the core on the histone spacer region assumes identical positions on circular DNA molecules in both the presence and absence of excess negative superhelical stress equivalent to sigma = -0.03. This result indicates that conservative levels of negative supercoiling do not induce a shift in the positions of nucleosome cores. The biological implications of the experimental results are discussed and related to the findings of other workers.

Enrichment of a fraction toxic to guinea-pigs from Pachystigma pygmaeum (Schltr.) Robyns.

Pachystigma pygmaeum is one of several species of rubiaceous plants which cause delayed heart failure among ruminants after their ingestion at relatively high doses. Using guinea-pigs for toxicity determinations, we were able to separate and enrich a toxic fraction from a fermentation extract of the plant material by countercurrent distribution. It contained virtually no potassium salts, passed through a 500 dalton selective membrane, exhibited lability under acid conditions and was toxic at 1 g/kg per os, with a delayed response of 3-4 days.