Molecular Forms of Acetylcholinesterase and Butyrylcholinesterase in Human Plasma and Cerebrospinal Fluid

The measurement of cholinesterase activities in either plasma or cerebrospinal fluid (CSF) may ultimately prove to be relevant in the diagnosis of neurological and neuropsychiatric disorders. However, studies to date have examined only total enzyme activities. Therefore in the present study we have examined the distribution of the individual molecular forms of both acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) in plasma and CSF using sucrose density gradient centrifugation. Although the total activities of AChE were of the same order of magnitude in plasma and CSF, there was a considerable difference (120-500-fold) between total BChE activity in the CSF and the BChE-rich plasma. The analysis of the individual molecular forms revealed that the predominant molecular species of AChE and BChE in the CSF--both lumbar and ventricular--was the G4 form. The G4 form also constituted the majority of the plasma BChE activity and, on average, over half (56%) of the plasma AChE activity. The significance of the AChE and BChE molecular form compositions of both plasma and CSF and their possible relationship to pathological states are discussed.     

Comparisons of tests for aneuploidy

The fundamental problems that face us in the development of suitable assay systems for the detection of potentially aneugenic (aneuploidy-inducing) chemicals include: (a) the diversity of cellular targets and mechanisms where perturbations of structure and function may give rise to changes in chromosome number, and (b) the phylogenetic differences that exist between species in their mechanism and kinetics of cell division and their metabolic profiles. A diverse range of assay systems have been developed, which have been shown to have potential for use in the detection of either changes in chromosome number or of perturbations of the events which may be causal in the induction of aneuploidy.

Chromosome number changes may be detected cytologically by karyotypic analysis, or by the use of specialised strains in which aneuploid progeny may be observed due to phenotypic differences with aneuploid parental cells or whole organisms. Techniques for the detection of cellular target modifications range from in vitro studies of tubulin polymerisation to observations of the behaviour of various cellular organelles and their fidelity of action during the division cycle.

The diversity of mechanisms which may give rise to aneuploidy and the qualitative relevance of events observed in experimental organisms compared to man make it unlikely that the detection and risk assessment of the aneugenic activity of chemicals will be possible using a single assay system. Optimal screening and assessment procedures will thus be dependent upon the selection of an appropriate battery of predictive tests for the measurement of the potentially damaging effects of aneuploidy induction.     

Purification and characterization of glutathione reductase from corn mesophyll chloroplasts

Differences in the apparent molecular weights of the subunits of glutathione reductase (EC 1.6.4.2) from pea chloroplasts and corn mesophyll chloroplasts have been recently reported. In order to more fully describe the differences between the enzymes from these two sources, glutathione reductase from the mesophyll chloroplasts of corn seedlings ( Zea mays L. cv. G-4507) has been purified 200-fold by affinity chromatography using adenosine 2',5'-disphosphate agarose. The purified enzyme had a specific activity of 26 μmol NADPH oxidized (mg protein)^-1 min^-1. The native enzyme had a relative molecular weight of 190 ± 30 kDa and exhibited polypeptides of 65, 63, 34, and 32 kDa when separated on sodium dodecylsulfate-polyacrylamide gels. Comparisons of the results from electroblotting, native molecular weight and subunit molecular weight analyses suggest that the enzyme exists as a heterotetramer. Optimal enzyme activity was obtained at pH 8 in N-2-hydroxyethyl-piperazine-N'-2-ethanesulfonic acid (HEPES-NaOH) buffer. The sulfhydryl reagent, n -ethylmaleimide, inhibited enzymatic activity when incubated in the presence of NADPH while no inhibition was detected with oxidized glutathione in the incubation mixture. Reduced glutathione (5 m M ) inactivated the enzyme by 50%. This inactivation followed first order kinetics with a rate constant of 0.0028 s^-1. The enzyme was also inactivated by NADPH. The inactivation reached ca 90% within 30 min and followed first order kinetics with a rate constant of 0.0015 s^-1.     

Development at Cold-Hardening Temperatures : The Structure and Composition of Purified Rye Light Harvesting Complex II

Light harvesting complex II (LHCII) was purified from cold-hardened (RH) and nonhardened winter rye (RNH) (Secale cereale L. cv Puma) employing a modified procedure of JJ Burke, CL Ditto, CJ Arntzen (Arch Biochem Biophys 187: 252-263). Triton X-100 solubilization of thylakoid membranes followed by three successive precipitations with 100 mm KCl and 10 mm MgCl₂ resulted in yields of up to 25% on a chlorophyll (Chl) basis and a purity of 90 to 95%, based on polypeptide analysis within 4 hours. Polypeptide and pigment analyses, 77 K fluorescence emission and room temperature absorption spectra indicate the LHCII obtained by this modified method is comparable to LHCII obtained by other published methods. Comparison of purified RH and RNH LHCII indicated no significant differences with respect to polypeptide, amino acid, Chl, and carotenoid compositions as well as no differences in lipid content. However, RH LHCII differed from RNH LHCII specifically with respect to the fatty acid composition of phosphatidyldiacylglycerol only. RH LHCII exhibited a 54% lower trans-Δ³-hexadecenoic acid level associated with PG and a 60% lower oligomeric LHCII:monomeric LHCII (LHCII₁:LHCII₃) than RNH LHCII. Both RH and RNH LHCII exhibited a 5-fold enrichment in PG specifically. Complete removal of PG by enzymic hydrolysis resulted in a significant reduction in the oligomeric content of both RH and RNH LHCII such that LHCII₁:LHCII₃ of RH and RNH LHCII preparations were the same. This confirms that this specific compositional change accounts for the structural differences between RH and RNH LCHII observed in situ and in vitro.     

Characterization of three group A klebicin plasmids: localization of their E colicin immunity genes

We have investigated the immunity to E colicins conferred by three group A klebicin plasmids. pP5a, which encodes klebicin A1-P5, like pClo-DF13, confers immunity to colicin E6 on Escherichia coli K12, whilst pP5b and pP3, which encode klebicins A2-P5 and A3-P3 respectively, both confer immunity to colicin E3. We have determined the restriction endonuclease and functional maps of the three group A klebicin plasmids. By sub-cloning and transposon mutagenesis we have investigated the relationship between the klebicin immunity and the E colicin immunity conferred by these plasmids. The colicin E6 and the klebicin A1 immunity are encoded by a single gene present on pP5a. The colicin E3 and the klebicin A2 immunity are encoded by a single gene present on pP5b. The colicin E3 and the klebicin A3 immunity are encoded by separate genes present on pP3. Recombinant pML8412, which is derived from the ColE6-CT14 plasmid and encodes colicin E6 immunity, confers klebicin A1-P5 immunity upon Klebsiella pneumoniae UNF5023. Recombinant pKC23, which is derived from the ColE3-CA38 plasmid and confers colicin E3 immunity, confers immunity to klebicin A2-P5, but not to klebicin A3-P3.     

Recruitment of lysozyme as a major enzyme in the mouse gut: Duplication,divergence, and regulatory evolution

Summary Two major types of lysozymec (M and P) occur in the mouse genus,Mus, and have been purified from an inbred laboratory strain (C58/J) ofM. domesticus. They differ in physical, catalytic, and antigenic properties as well as by amino acid replacements at 6 of 49 positions in the amino-terminal sequence. Comparisons with four other mammalian lysozymesc of known sequence suggest that M and P are related by a gene duplication that took place before the divergence of the rat and mouse lineages. M lysozyme is present in most tissues; achieves its highest concentration in the kidney, lung, and spleen; and corresponds to the lysozyme partially sequenced before from another strain ofM. domesticus. InM. domesticus and several related species, P lysozyme was detected chiefly in the small intestine, where it is probably produced mainly by Paneth cells. A survey of M and P levels in 22 species of muroid rodents (fromMus and six other genera) of known phylogenetic relationships suggests that a mutation that derepressed the P enzyme arose about 4 million years ago in the ancestor of the housemouse group of species. Additional regulatory shifts affecting M and P levels have taken place along lineages leading to other muroid species. Our survey of 187 individuals of wild house mice and their closest allies reveals a correlation between latitude of origin and level of intestinal lysozyme.