Mapping of New Escherichia coli K and 15 Restriction Sites on Specific Fragments of Bacteriophage φX174 DNA

We have isolated several new phiX174 mutants which contain sites sensitive to restriction by Escherichia coli. One contains an E. coli 15 restriction site and three are double mutants containing an E. coli K site as well as the E. coli 15 site. The replicative form (RF) DNA of one of the mutants containing a K site has been shown to be restricted in spheroplasts of a K-12 strain. The infectivity of this RF, but not wild-type RF, has also been shown to be inactivated by an E. coli K extract and by purified K restriction enzyme in vitro. The product of the RF treated with purified K restriction enzyme in vitro is a full length linear molecule. The mutant sites have also been localized to specific regions of the phiX174 genome by a fragment mapping technique, making use of specific fragments of phiX174 RF DNA obtained by digestion with a specific endonuclease.     

Gene Interactions between Potassium-Sensitive and Potassium-Resistant Mutations of PARAMECIUM TETRAURELIA

Two unlinked recessive mutations (ks-1 and ks-2 ) have been induced in Paramecium tetraurelia stock 51. Wild-type survives and grows when up to 30 mm KCl is added to the medium, but the mutants cease to grow and die when added KCl reaches 20-25 m m. These K(+)-sensitives have been crossed to stocks containing the K(+)-resistant genes, fA (very resistant) and kA (moderately resistant). All four genes are unlinked. Double mutants of ks-1 and either kA or fA are as resistant as the resistant member of the pair. Doubles of ks-2 and kA are like wild type, and doubles of ks-2 and fA are shifted from high resistance toward wild type. Gene ks-2 acts like a suppressor of kA and fA. This suppression can be understood in terms of the known biochemical defects of the mutants.     

Influenza a viruses with mutations in the m1 helix six domain display a wide variety of morphological phenotypes

Several functions required for the replication of influenza A viruses have been attributed to the viral matrix protein (M1), and a number of studies have focused on a region of the M1 protein designated "helix six." This region contains an exposed positively charged stretch of amino acids, including the motif 101-RKLKR-105, which has been identified as a nuclear localization signal, but several studies suggest that this domain is also involved in functions such as binding to the ribonucleoprotein genome segments (RNPs), membrane association, interaction with the viral nuclear export protein, and virus assembly. In order to define M1 functions in more detail, a series of mutants containing alanine substitutions in the helix six region were generated in A/WSN/33 virus. These were analyzed for RNP-binding function, their capacity to incorporate into infectious viruses by using reverse genetics, the replication properties of rescued viruses, and the morphological phenotypes of the mutant virus particles. The most notable effect that was identified concerned single amino acid substitution mutants that caused significant alterations to the morphology of budded viruses. Whereas A/WSN/33 virus generally forms particles that are predominantly spherical, observations made by negative stain electron microscopy showed that several of the mutant virions, such as K95A, K98A, R101A, and K102A, display a wide range of shapes and sizes that varied in a temperature-dependent manner. The K102A mutant is particularly interesting in that it can form extended filamentous particles. These results support the proposition that the helix six domain is involved in the process of virus assembly.     

Characterization of low potassium-resistant mutants of the Madin-Darby canine kidney cell line with defects in NaCl/KCl symport

Three independent mutants of the Madin-Darby canine kidney cell line (MDCK) have been isolated which were capable of growth in media containing low concentrations of potassium. All three mutants were deficient to varying extents in furosemide- and bumetanide-sensitive 22Na+, 86+b+, and 36Cl- uptake. The two mutants most resistant to low K+ media had lost essentially all of the 22Na+, 86Rb+, and 36Cl- uptake activities of this system. The third mutant was partially resistant to low K+ media and had reduced levels of bumetanide-sensitive uptake for all three ions. Extrapolated initial uptake rates for 22Na+, 86Rb+, and 36Cl- revealed that the partial mutant exhibited approximately 50% of the parental uptake rates for all three ions. The stoichiometries of bumetanide-sensitive uptake in both the parental cell line and the partial mutant approximated 1 Rb+:1 Na+:2 Cl-. The results of this study provide genetic evidence for a single tightly-coupled NaCl/KCl symporter in MDCK cells. The correlation between the ability to grow in low K+ media and decreased activity of the bumetanide-sensitive co-transport system suggests that the bumetanide-sensitive transport system catalyzes net K+ efflux from cells in low K+ media. The results of 86Rb+ efflux studies conducted on ouabain-pretreated mutant and parental cells are consistent with this interpretation. Cell volume measurements made on cells at different densities in media containing normal K+ concentrations showed that none of the mutants differed significantly in volume from the parental strain at a similar cell density. Furthermore, all three mutants were able to readjust their volume after suspension in hypotonic media. These results suggest that in the MDCK cell line, the bumetanide-sensitive NaCl/KCl symport system does not function in the regulation of cell volume under the conditions employed.     

Genetic analysis of second-site revertants of bacteriophage lambda integrase mutants.

Bacteriophage lambda site-specific recombination is catalyzed by the phage-encoded integrase (Int) protein. Using a collection of 21 recombination-defective Int mutants, we performed a second-site reversion analysis. One of the primary mutants contained a valine-to-glutamic acid change at position 175 (V175E), and a pseudorevertant with a lysine change at this site (V175K) was also isolated. Relative to the wild-type protein, the V175E protein was defective in its ability to form the attL complex and to catalyze excision in vivo and in vitro. A mutant containing an alanine substitution (V175A) was made by site-directed mutagenesis, and it was more efficient than the V175K protein in forming the attL complex and promoting excision. These results indicate that a nonpolar side chain at residue 175 is required for function. The second primary mutant contained a proline-to-leucine change at position 243 (P243L). A true second-site revertant was isolated that contained a glutamic acid-to-lysine change (E218K). The P243L-E218K protein promoted recombination and bound arm-type sites more efficiently than the original P243L protein but not as efficiently as the protein containing the E218K substitution alone. The E218K substitution also restored activity to a mutant with a threonine-to-isoleucine substitution at position 270 (T270I). This result showed that suppression by the E218K change is not allele specific and suggests that the substitution improves an inherent activity of Int rather than directly compensating for the defect caused by the primary substitutions. Results with challenge phages carrying attL sites with altered core sites indicate that the E218K change may improve binding to the core site.     

Structure and evolution of a novel dimeric enzyme from a clinically important bacterial pathogen

Dihydrodipicolinate synthase (DHDPS) catalyzes the first committed step of the lysine biosynthetic pathway. The tetrameric structure of DHDPS is thought to be essential for enzymatic activity, as isolated dimeric mutants of Escherichia coli DHDPS possess less than 2.5% that of the activity of the wild-type tetramer. It has recently been proposed that the dimeric form lacks activity due to increased dynamics. Tetramerization, by buttressing two dimers together, reduces dynamics in the dimeric unit and explains why all active bacterial DHDPS enzymes to date have been shown to be homo-tetrameric. However, in this study we demonstrate for the first time that DHDPS from methicillin-resistant Staphylococcus aureus (MRSA) exists in a monomer-dimer equilibrium in solution. Fluorescence-detected analytical ultracentrifugation was employed to show that the dimerization dissociation constant of MRSA-DHDPS is 33 nm in the absence of substrates and 29 nm in the presence of (S)-aspartate semialdehyde (ASA), but is 20-fold tighter in the presence of the substrate pyruvate (1.6 nm). The MRSA-DHDPS dimer exhibits a ping-pong kinetic mechanism (k(cat)=70+/-2 s(-1), K(m)(Pyruvate)=0.11+/-0.01 mm, and K(m)(ASA)=0.22+/-0.02 mm) and shows ASA substrate inhibition with a K(si)(ASA) of 2.7+/-0.9 mm. We also demonstrate that unlike the E. coli tetramer, the MRSA-DHDPS dimer is insensitive to lysine inhibition. The near atomic resolution (1.45 A) crystal structure confirms the dimeric quaternary structure and reveals that the dimerization interface of the MRSA enzyme is more extensive in buried surface area and noncovalent contacts than the equivalent interface in tetrameric DHDPS enzymes from other bacterial species. These data provide a detailed mechanistic insight into DHDPS catalysis and the evolution of quaternary structure of this important bacterial enzyme.     

Vanadate-Resistant Mutants of Neurospora crassa Are Deficient in a High-Affinity Phosphate Transport System

Mutant strains of Neurospora crassa have been selected which grow on media containing vanadate, an inhibitor of the plasma membrane ATPase. The mutations all map to a single region (designated van) on the left arm of linkage group VII. The van mutants are unable to take up vanadate from the medium and are also deficient in the uptake of phosphate via a derepressible, high-affinity phosphate transport system. In the van mutants, the K(m) for phosphate transport is elevated as much as 35-fold, indicating that the van locus may code for a structural component of the high-affinity phosphate transport system.     

Impact of Nox5 Polymorphisms on Basal and Stimulus-Dependent ROS Generation

Nox5 is an EF-hand containing, calcium-dependent isoform of the NADPH oxidase family of reactive oxygen species (ROS) generating enzymes. Altered expression and activity of Nox5 has been reported in cardiovascular diseases and cancers but the absence of Nox5 in rodents has precluded a greater understanding of its physiological and pathophysiological roles. Multiple polymorphisms have been identified within the coding sequence of human Nox5, but whether this translates into altered enzyme function is unknown. Herein, we have generated 15 novel mutants of Nox5β to evaluate the effect of exonic SNPs on basal and stimulated enzyme activity. Compared to the WT enzyme, ROS production was unchanged or slightly modified in the majority of mutants, but significantly decreased in 7. Focusing on M77K, Nox5 activity was dramatically reduced in unstimulated cells and following challenge with both calcium- and phosphorylation-dependent stimuli despite equivalent levels of expression. The M77K mutation did not influence the Nox5 phosphorylation or the ability to bind Hsp90, but in cell-free assays with excess co-factors and calcium, ROS production was dramatically reduced. A more conservative substitution M77V arising from another SNP yielded a different profile of enzyme activity and suggests a critical role of M77 in calcium-dependent ROS production. Two C-terminal mutants, R530H and G542R, were observed that had little to no activity and relatively high minor allele frequency (MAF). In conclusion, we have identified 7 missense SNPs in Nox5 that result in little or no enzyme activity. Whether humans with dysfunctional Nox5 variants have altered physiology or disease remains to be determined.     

Cysteine-scanning mutagenesis of an eukaryotic pore-forming toxin from sea anemone: topology in lipid membranes.

Equinatoxin II is a cysteineless pore-forming protein from the sea anemone Actinia equina. It readily creates pores in membranes containing sphingomyelin. Its topology when bound in lipid membranes has been studied using cysteine-scanning mutagenesis. At approximately every tenth residue, a cysteine was introduced. Nineteen single cysteine mutants were produced in Escherichia coli and purified. The accessibility of the thiol groups in lipid-embedded cysteine mutants was studied by reaction with biotin maleimide. Most of the mutants were modified, except those with cysteines at positions 105 and 114. Mutants R144C and S160C were modified only at high concentrations of the probe. Similar results were obtained if membrane-bound biotinylated mutants were tested for avidin binding, but in this case three more mutants gave a negative result: S1C, S13C and K43C. Furthermore, mutants S1C, S13C, K20C, K43C and S95C reacted with biotin only after insertion into the lipid, suggesting that they were involved in major conformational changes occurring upon membrane binding. These results were further confirmed by labeling the mutants with acrylodan, a polarity-sensitive fluorescent probe. When labeled mutants were combined with vesicles, the following mutants exhibited blue-shifts, indicating the transfer of acrylodan into a hydrophobic environment: S13C, K20C, S105C, S114C, R120C, R144C and S160C. The overall results suggest that at least two regions are embedded within the lipid membrane: the N-terminal 13-20 region, probably forming an amphiphilic helix, and the tryptophan-rich 105-120 region. Arg144, Ser160 and residues nearby could be involved in making contacts with lipid headgroups. The association with the membrane appears to be unique and different from that of bacterial pore-forming proteins and therefore equinatoxin II may serve as a model for eukaryotic channel-forming toxins.     

Discovery of a novel site regulating glucokinase activity following characterization of a new mutation causing hyperinsulinemic hypoglycemia in humans

Type 2 diabetes is a global problem, and current ineffective therapeutic strategies pave the way for novel treatments like small molecular activators targeting glucokinase (GCK). GCK activity is fundamental to beta cell and hepatocyte glucose metabolism, and heterozygous activating and inactivating GCK mutations cause hyperinsulinemic hypoglycemia (HH) and maturity onset diabetes of the young (MODY) respectively. Over 600 naturally occurring inactivating mutations have been reported, whereas only 13 activating mutations are documented to date. We report two novel GCK HH mutations (V389L and T103S) at residues where MODY mutations also occur (V389D and T103I). Using recombinant proteins with in vitro assays, we demonstrated that both HH mutants had a greater relative activity index than wild type (6.0 for V389L, 8.4 for T103S, and 1.0 for wild type). This was driven by an increased affinity for glucose (S(0.5), 3.3 ± 0.1 and 3.5 ± 0.1 mm, respectively) versus wild type (7.5 ± 0.1 mm). Correspondingly, the V389D and T103I MODY mutants had markedly reduced relative activity indexes (<0.1). T103I had an altered affinity for glucose (S(0.5), 24.9 ± 0.6 mm), whereas V389D also exhibited a reduced affinity for ATP and decreased catalysis rate (S(0.5), 78.6 ± 4.5 mm; ATP(K(m)), 1.5 ± 0.1 mm; K(cat), 10.3 ± 1.1s(-1)) compared with wild type (ATP(K(m)), 0.4 ± <0.1; K(cat), 62.9 ± 1.2). Both Thr-103 mutants showed reduced inhibition by the endogenous hepatic inhibitor glucokinase regulatory protein. Molecular modeling demonstrated that Thr-103 maps to the allosteric activator site, whereas Val-389 is located remotely to this position and all other previously reported activating mutations, highlighting α-helix 11 as a novel region regulating GCK activity. Our data suggest that pharmacological manipulation of GCK activity at locations distal from the allosteric activator site is possible.     

Isolation and characterization of magbane, a magnesium-lethal mutant of paramecium.

Discerning the mechanisms responsible for membrane excitation and ionic control in Paramecium has been facilitated by the availability of genetic mutants that are defective in these pathways. Such mutants typically are selected on the basis of behavioral anomalies or resistance to ions. There have been few attempts to isolate ion-sensitive strains, despite the insights that might be gained from studies of their phenotypes. Here, we report isolation of "magbane," an ion-sensitive strain that is susceptible to Mg2+. Whereas the wild type tolerated the addition of > or =20 mm MgCl2 to the culture medium before growth was slowed and ultimately suppressed (at >40 mm), mgx mutation slowed growth at 10 mm. Genetic analysis indicated that the phenotype resulted from a recessive single-gene mutation that had not been described previously. We additionally noted that a mutant that was well described previously (restless) is also highly sensitive to Mg2+. This mutant is characterized by an inability to control membrane potential when extracellular K+ concentrations are lowered, due to inappropriate regulation of a Ca2+-dependent K+ current. However, comparing the mgx and rst mutant phenotypes suggested that two independent mechanisms might be responsible for their Mg2+ lethality. The possibility that mgx mutation may adversely affect a transporter that is required for maintaining low intracellular Mg2+ is considered.     

Characterization of Altered Forms of Glycyl Transfer Ribonucleic Acid Synthetase and the Effects of Such Alterations on Aminoacyl Transfer Ribonucleic Acid Synthesis In Vivo

The glycyl transfer ribonucleic acid (tRNA) synthetase (GRS) activities of several Escherichia coli glyS mutants have been partially characterized; the K(m) for glycine and the apparent V(max) of several of the altered GRS differ significantly from the parental GRS. Paradoxically, some of the altered forms exhibit more activity in vitro than the GRS from a prototrophic strain (GRS(L)); several parameters of these activities have been studied in an attempt to resolve this problem. The amount of acylated tRNA(Gly) in vivo was examined to assess the GRS activities inside the cells. During exponential growth in media containing glycine, moderate amounts of acylated tRNA(Gly) occur in the glyS mutants; glycine deprivation leads to a dramatic drop in the amount of acylated tRNA(Gly). An alternative measure of the in vivo activities of the altered enzymes is the efficiency of suppression of the trpA36 locus by su(36) (+); glyS mutants grown with added glycine exhibit one-third to one-fourth the suppression efficiency of the prototrophic glyS(H) parent, presumably because they are less efficient, even in the presence of high levels of glycine, in charging the tRNA(Gly) species which functions as the translational suppressor.     

Histidyl-transfer ribonucleic acid synthetase mutants requiring a high internal pool of histidine for growth

Mutants that require histidine due to an altered structural gene for the histidyl-transfer ribonucleic acid synthetase (hisS) have been isolated by a general selection for histidine-requiring strains in which the mutation producing histidine auxotrophy is unlinked to the histidine operon. One of the mutants has been shown to require an abnormally high internal histidine pool for growth owing to an altered synthetase that is unstable at low histidine concentrations. It is difficult to determine accurately the K(m) for histidine of the synthetase enzyme from the mutant because of the instability of the enzyme at limiting histidine concentrations; however, a histidine K(m) value has been estimated that is approximately 100 times higher than the histidine K(m) of the wild-type enzyme. For the mutant strains to achieve the high internal pool of histidine required for growth, all the systems that transport histidine from the growth medium must be functioning to capacity. Amino acids that interfere with histidine transport strongly inhibit the growth of the mutants. The mutants have been useful in providing a selective genetic marker for transductional mapping in the hisS region. The mutants are discussed as representative of a general class of curable mutants that have an altered enzyme with poor affinity for a substrate or coenzyme.     

Kluyveromyces lactis sexual pheromones. Gene structures and cellular responses to alpha-factor

The Kluyveromyces lactis genes for sexual pheromones have been analyzed. The alpha-factor gene encodes a predicted polypeptide of 187 amino acid residues containing four tridecapeptide repeats (WSWITLRPGQPIF). A nucleotide blast search of the entire K. lactis genome sequence allowed the identification of the nonannotated putative a-pheromone gene that encodes a predicted protein of 33 residues containing one copy of the dodecapeptide a-factor (WIIPGFVWVPQC). The role of the K. lactis structural genes KlMFalpha1 and KlMFA1 in mating has been investigated by the construction of disruption mutations that totally eliminate gene functions. Mutants of both alleles showed sex-dependent sterility, indicating that these are single-copy genes and essential for mating. MATalpha, Klsst2 mutants, which, by analogy to Saccharomyces cerevisiae, are defective in Galpha-GTPase activity, showed increased sensitivity to synthetic alpha-factor and increased capacity to mate. Additionally, Klbar1 mutants (putatively defective in alpha-pheromone proteolysis) showed delay in mating but sensitivity to alpha-pheromone. From these results, it can be deduced that the K. lactis MATa cell produces the homolog of the S. cerevisiaealpha-pheromone, whereas the MATalpha cell produces the a-pheromone.     

Functional aberration of myofibrils by cardiomyopathy-causing mutations in the coiled-coil region of the troponin-core domain

Two cardiomyopathy-causing mutations, E244D and K247R, in human cardiac troponin T (TnT) are located in the coiled-coil region of the Tn-core domain. To elucidate effects of mutations in this region on the regulatory function of Tn, we measured Ca²⁺-dependent ATPase activity of myofibrils containing various mutants of TnT at these residues. The results confirmed that the mutant E244D increases the maximum ATPase activity without changing the Ca²⁺-sensitivity. The mutant K247R was shown for the first time to have the effect similar to the mutant E244D. Furthermore, various TnT mutants (E244D, E244M, E244A, E244K, K247R, K247E, and K247A) showed various effects on the maximum ATPase activity while the Ca²⁺-sensitivity was unchanged. Molecular dynamics simulations of the Tn-core containing these TnT mutants suggested that the hydrogen-bond network formed by the side chains of neighboring residues around residues 244 and 247 is important for Tn to function properly.     

Copper(I) interaction with model peptides of WD6 and TM6 domains of Wilson ATPase: regulatory and mechanistic implications

With the aim to investigate the mechanism of Cu(I) transport by Wilson ATPase (ATP7B), we have studied the interaction of the peptides 2K10p (CH(3)CO-Lys-Gly-Met-Thr-Cys-Ala-Ser-Cys-Val-His-Asn-Lys-CONH(2)), and 2K8p (CH(3)CO-Lys-Leu-Cys-Ile-Ala-Cys-Pro-Cys-Ser-Lys-CONH(2)), part of the sixth metal binding domain (WD6) and the sixth transmembrane segment (TM6) of Wilson ATPase, respectively, by means of CD, NMR spectroscopy and homology modeling. In addition, the interaction of Cu(I) with the 2K8p mutants 1s (CH(3)CO-Lys-Leu-Ser-Ile-Ala-Cys-Pro-Cys-Ser-Lys-CONH(2)), 2s (CH(3)CO-Lys-Leu-Cys-Ile-Ala-Ser-Pro-Cys-Ser-Lys-CONH(2)) and 3s (CH(3)CO-Lys-Leu-Cys-Ile-Ala-Cys-Pro-Ser-Ser-Lys-CONH(2)), containing two cysteines in various positions, have been studied with the same methods, in order to understand the role of each cysteine in copper binding. Our studies show that the three cysteine thiolates present in the 2K8p peptide sequence act mainly as bridging ligands for Cu(I) binding, and dithiothreitol acts as an important ligand in Cu(I) ligation by 2K10p and the 2K8p mutants. Formation of oligomeric species has been evidenced for all peptides except 2s. Shift of the equilibrium between the various oligomeric species has been accomplished by reducing the Cu(I):peptide ratio. Significant shifts of proline protons upon interaction with Cu(I) have been observed for all proline containing peptides implying a possible role of proline in facilitating Cu(I) binding. These findings have been further discussed with respect to the molecular basis of copper trafficking and intermolecular interactions.     

The enzymic interconversion of acetate and acetyl-coenzyme A in Escherichia coli.

Mutants of Escherichia coli K12 have been isolated that grow on media containing pyruvate of proline as sole carbon sources despite the presence of 10 or 50 mM-sodium fluoroacetate. Such mutants lack either acetate kinase [ATP: acetate phosphotransferase; EC 2.7.2.1] or phosphotransacetylase [acetyl-CoA: orthophosphate acetyltransferase; EC 2.3.1.8] activity. Unlike wild-type E. coli, phosphotransacetylase mutants do not excrete acetate when growing aerobically or anaerobically on glucose; their anaerobic growth on this sugar is slow. The genes that specify acetate kinase (ack) and phosphotransacetylase (pta) activities are cotransducible with each other and with purF and are thus located at about min 50 on the E. coli linkage map. Although Pta- and Ack- mutants are greatly impaired in their growth on acetate, they incorporate [2-14C]acetate added to cultures growing on glycerol, but not on glucose. An inducible acetyl-CoA synthetase [acetate: CoA ligase (AMP-forming); EC 6.2.1.1] effects this uptake of acetate.     

An anomaly in potassium accumulation by barley roots: I. Effect of anions, sodium concentration, and length of absorption period

Excised barley roots accumulated 40 to 50% more K(+) from 0.04 mm than from 0.06 mm KCl when incubated for 24 hours in KCl solutions containing 0.2 mm CaSO(4). This phenomenon was not markedly influenced by the rate of absorption of the counteranion. The presence of Na(+) in the treatment solutions decreased total K accumulation but did not alter the K(+) concentration at which the accumulation peak occurred. Short interval studies indicated that this phenomenon is easily observable after 4 hours and begins to become apparent within 2 hours. In comparison with barley, accumulation of K(+) by excised wheat roots decreased as KCl concentration was increased from 0.02 to 0.06 mm; but K(+) accumulation curve for corn roots showed no peaks or depressions in the concentration range of 0.01 to 0.1 mm. A normal hyperbolic curve was noted for the accumulation of Na(+) from 0.01 to 1 mm NaCl by barley roots.     

Impact of mitochondrial function on yeast susceptibility to antifungal compounds

Saccharomyces cerevisiae pell and crd1 mutants deficient in the biosynthesis of mitochondrial phosphatidylglycerol (PG) and cardiolipin (CL) as well as Kluyveromyces lactis mutants impaired in the respiratory chain function (RCF) containing dysfunctional mitochondria show altered sensitivity to metabolic inhibitors. The S. cerevisiae pell mutant displayed increased sensitivity to cycloheximide, chloramphenicol, oligomycin and the cell-wall perturbing agents caffeine, caspofungin and hygromycin. On the other hand, the pel1 mutant was less sensitive to fluconazole, similarly as the K. lactis mutants impaired in the function of mitochondrial cytochromes. Mitochondrial dysfunction resulting either from the absence of PG and CL or impairment of the RCF presumably renders the cells more resistant to fluconazole. The increased tolerance of K. lactis respiratory chain mutants to amphotericin B, caffeine and hygromycin is probably related to a modification of the cell wall.     

Effect of nuclear mutation in maize on photosynthetic activity and content of chlorophyll-protein complexes

A number of new nuclear mutants have been isolated from maize by selection for high chlorophyll (Chl) fluorescence. These mutants show reduced rates of photosynthesis and/or are deficient in Chl. Electrophoretic examination of wild type thylakoid membranes revealed five Chl-protein complexes, two containing only Chl a and three containing Chl a and Chl b. A class of nonviable, photosystem I-deficient mutants was found to be lacking one (A-1) of the two Chl a-protein complexes. A second class of nonviable, photosystem I-lacking mutants was found to be missing not only this A-1 complex but also one or more of the three Chl a and b-containing, light-harvesting Chl-protein complexes. Viable mutants were obtained which appeared to have lost just one of the Chl b-containing complexes, whereas a second class of viable mutants was missing all three of the Chl b-complexes. The results confirm that the A-1 band is associated with the P700-Chl a-protein complex characterized previously. The data also indicate the existence of structurally different forms of the light-harvesting Chl a- and b-containing complexes. The results also show a lower molecular weight band (A-2) containing primarily Chl a and which appears to be required for viability.