Actinobacteria are closely linked to human life as industrial producers of bioactive molecules and as human pathogens. Respiratory cytochrome bcc complex and cytochrome aa3 oxidase are key components of their aerobic energy metabolism. They form a supercomplex in the actinobacterial species Corynebacterium glutamicum. With comprehensive bioinformatics and phylogenetic analysis we show that genes for cyt bcc-aa3 supercomplex are characteristic for Actinobacteria (Actinobacteria and Acidimicrobiia, except the anaerobic orders Actinomycetales and Bifidobacteriales). An obligatory supercomplex is likely, due to the lack of genes encoding alternative electron transfer partners such as mono-heme cyt c. Instead, subunit QcrC of bcc complex, here classified as short di-heme cyt c, will provide the exclusive electron transfer link between the complexes as in C. glutamicum. Purified to high homogeneity, the C. glutamicum bcc-aa3 supercomplex contained all subunits and cofactors as analyzed by SDS-PAGE, BN-PAGE, absorption and EPR spectroscopy. Highly uniform supercomplex particles in electron microscopy analysis support a distinct structural composition. The supercomplex possesses a dimeric stoichiometry with a ratio of a-type, b-type and c-type hemes close to 1:1:1. Redox titrations revealed a low potential bcc complex (Em(ISP)=+160mV, Em(bL)=-291mV, Em(bH)=-163mV, Em(cc)=+100mV) fined-tuned for oxidation of menaquinol and a mixed potential aa3 oxidase (Em(CuA)=+150mV, Em(a/a3)=+143/+317mV) mediating between low and high redox potential to accomplish dioxygen reduction. The generated molecular model supports a stable assembled supercomplex with defined architecture which permits energetically efficient coupling of menaquinol oxidation and dioxygen reduction in one supramolecular entity.
_ . _ --Plasma membranes from three week old leaves of Vicia foba L. were enriched by aqueous twophase partitioning to high purity. Plasma membrane proteins were immunoblotted with polyclonal, monospecific antibodies raised against mouse liver connexins (ex) 32 and 26. Immunostaining after treatments with ex BSA: 32 antibodies revealed the existence of a 29 kDa protein, clearly enriched in the plasma membrane fraction, An additional immunoreactive band of 20 kDa, possibly a degradation product of the 29 kDa protein, was found in the soluble fraction. When immunoblots were incubated with ex 26 antibodies, a 40 kDa band with a strong immunoresponse appeared, assumed to present the dimeric form of a 21 kDa, ex 26-like plant protein. The monomeric form could be only obtained when intact leaf material or mesophyll protoplasts from three week old plants were directly SDS-extracted. Furthermore, in young, one week old leaves, the monomer seems to exist in larger amounts, Tris:I together with another crossreacting 35 kDa protein. The 29 kDa (ex 32-related) as well as the 40 kDa (ex 26-. related) polypeptide is obviously located in the plasma
A strong age dependency together with alterations in the cellular distribution of CX 26 immunorelated protein(s) was found for differently developed leaves of Vicia faba L. With increasing age, an immunoreactive 40 kD band was observed in the soluble and microsomal fraction. In the cell wall protein preparation of young and fully differentiated leaves the 40 kD band was the minor constituent. A 33 kD polypeptide was dominantly localized in the microsomal fractions of all developmental stages and in SDS‐extracts of total cell proteins of young leaves. A 21 kD protein together with a 16 kD polypeptide was associated with the cell wall fraction. The 21 kD protein, assumed to represent a plasmodesmatal constituent, was reduced with age. In SDS extracts, prepared from the different developmental stages of the leaves and of mesophyll protoplasts, the age‐dependent appearance of the several immunostained bands was most obvious. A correlation of the 16, 33, and 40 kD bands to a turnover of the 21 kD protein is suggested. The reduced amount of the 21 kD protein with increasing age may be contemplated as an indication for a relative decrease of symplastic connections between cells of maturing leaves. This is in agreement with the results obtained by immunofluorescence studies using guard cell protoplasts. Here, observations pointed also to a reduction and final loss of CX 26‐related protein at the protoplast surfaces.
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