Amino acid sequence of beta-galactosidase. XI. Peptide ordering procedures and the complete sequence.

The amino acid sequence of beta-galactosidase has been determined. The monomer contains 1,021 amino acid residues in a single polypeptide chain and has a molecular weight of 116,349. All 80 tryptic peptides as well as all 24 CNBr peptides have been isolated in pure form. Evidence is presented for the ordering of the CNBr peptides. The sequence determination was aided by analysis of cyanogen bromide peptides obtained from a polypeptide fragment produced by a lacZ termination mutant strain.     

Molecular Cloning of the Wild-Type and Mutant thyA Gene from Shigella flexneri Y

The thyA gene which codes for thymidylate synthase has been cloned and sequenced from the wild-type Shigella flexneri Y strain SH4 and a thyA mutant TSF21 after amplifying the gene by polymerase chain reaction (PCR). The nucleotide sequence revealed 98% homology to the E. coli K-12 thyA gene. The sequence of the wild-type thyA gene of Shigella flexneri Y was identical with that of the thyA mutant except that the residue T at position 345 was replaced by residue A in the thyA mutant. This change would cause a predicted amino acid substitution of leucine at position 44 in the polypeptide product of the wild type by glutamine in the mutant. Thus, Leu⁴⁴ may be critical in enzymatic activity of the thyA gene product thymidylate synthase.     

Biochemical characterization of peptides from herpes simplex virus glycoprotein gC: loss of CNBr fragments from the carboxy terminus of truncated, secreted gC molecules.

A biochemical characterization of peptides from herpes simplex virus type 1 glycoprotein gC was carried out. We utilized simple micromethods, based on immunological isolation of biosynthetically radiolabeled gC, to obtain gC in pure form for biochemical study. CNBr fragments of gC were prepared, isolated, and characterized. These CNBr fragments were resolved into six peaks by chromatography on Sephacryl S-200 in 6 M guanidine hydrochloride. Only three of the CNBr fragments contained carbohydrate side chains, as judged from the incorporation of [14C]glucosamine. Radiochemical microsequence analyses were carried out on the gC molecule and on each of the CNBr fragments of gC. A comparison of this amino acid sequence data with the amino acid sequence predicted from the DNA sequence of the gC gene showed that the first 25 residues of the predicted sequence are not present in the gC molecule isolated from infected cells and allowed alignment of the CNBr fragments in the gC molecule. Glycoprotein gC was also examined from three gC mutants, synLD70, gC-8, and gC-49. These mutants lack an immunoreactive envelope form of gC but produce a secreted, truncated gC gene product. Glycoprotein gC from cells infected with any of these gC- mutants was shown to have lost more than one CNBr fragment present in the wild-type gC molecule. The missing fragments included the one containing the putative transmembrane anchor sequence. Glycoprotein gC from the gC-8 mutant was also shown, by tryptic peptide map analysis, to have lost more than five major arginine-labeled tryptic peptides arginine-labeled tryptic peptides present in the wild-type gC molecule and to have gained a lysine-labeled tryptic peptide not present in wild-type gC.     

A Chlamydomonas outer arm dynein mutant missing the alpha heavy chain

A novel Chlamydomonas flagellar mutant (oda-11) missing the alpha heavy chain of outer arm dynein but retaining the beta and gamma heavy chains was isolated. Restriction fragment length polymorphism analysis with an alpha heavy chain locus genomic probe indicated that the oda-11 mutation was genetically linked with the structural gene of the alpha heavy chain. In cross-section electron micrographs, the oda-11 axoneme lacked the outermost appendage of the outer arm, indicating that the alpha heavy chain should be located in this region in the wild-type outer arm. This mutant swam at 119 microns/s at 25 degrees C, i.e., at an intermediate speed between those of wild type (194 microns/s) and of oda-1 (62 microns/s), a mutant missing the entire outer dynein arm. The flagellar beat frequency (approximately 50 Hz) was also between those of wild type (approximately 60 Hz) and oda-1 (approximately 26 Hz). These results indicate that the outer dynein arm of Chlamydomonas can be assembled without the alpha heavy chain, and that the outer arm missing the alpha heavy chain retains partial function.     

Human complement component C1s. Partial sequence determination of the heavy chain and identification of the peptide bond cleaved during activation

Human C1s proenzyme (Mr 83 000) was isolated by a rapid two-stage method involving affinity chromatography of C1 on IgG-Sepharose and isolation of subcomponent C1s by ion-exchange chromatography on DEAE-Sephacel. Single-chain C1s proenzyme was activated to two-chain C1s with self-activated C1r. After reduction and S-carboxamidomethylation the heavy chain of C1s (Mr 57 000) was isolated by ion exchange chromatography on DEAE-Sephacel. Cleavage of C1s heavy chain with CNBr yielded five fragments whose N-terminal sequences were determined. The alignment of the fragments within the heavy chain was established by tryptic peptides containing methionine. C1s heavy chain comprises about 470 amino acid residues and 42% of its sequence was determined. An intrachain sequence homology and a homology to the alpha 2 chain of human haptoglobin were identified. The C-terminal CNBr fragment comprising 44 amino acid residues was completely sequenced. From BNPS-skatole cleavage of reduced and alkylated C1s proenzyme a fragment was isolated which overlaps the C1s heavy and light chain parts and which contains the peptide bond cleaved during activation. The results show that this is an Arg-Ile bond and that under standard conditions of activation no peptide material is liberated from this portion of the molecule. The sequence data and homology to two-chain serine proteases indicate a single interchain disulfide bond in C1s.     

Covalent structural analysis of yeast inorganic pyrophosphatase: Location of groups implicated in the catalytic function; placement of the NH2-terminal 100 residues in the subunit

Covalent structural analysis of two of the three cyanogen bromide fragments from yeast inorganic pyrophosphatase (EC 3.6.1.1, pyrophosphate phosphohydrolase) was undertaken by a strategy involving both automated Edman degradation and conventional sequence analysis. Automated degradation of intact, reduced and carboxymethylated pyrophosphatase provided the sequence of the first 34 residues in the NH₂-terminal 45-residue peptide, CNBr VI, in addition to a partial sequence through 50 cycles which confirmed the overlap into the internal fragment, CNBr III. The sequence of CNBr VI was completed through analysis of peptides derived from hydrolysis of the fragment with trypsin and chymotrypsin. Structural analysis of CNBr III has provided the sequence of the first 55 amino acids in this 103-residue fragment. The sequence was established by conventional and automated procedures applied to the analysis of tryptic peptides generated from the citraconylated fragment. These findings constitute the sequence of the first 100 residues in the pyrophosphatase subunit and, together with structural information obtained earlier, define over half of the covalent structure of the molecule. Moreover, the sequence derived thus far permits the placement of a number of amino acids that are of importance relative to studies of the enzyme mechanism, and with regard to analysis of its three-dimensional structure.     

Amino Acid Sequence of Cyanogen Bromide Fragment CB I from Ala Chain of Ricin D

The amino acid sequence of the cyanogen bromide (CNBr) fragment CB I from the Ala chain of ricin D, the largest of three CNBr fragments, was established by manual Edman degradation of the peptides obtained by tryptic, chymotryptic or peptic digestion of fragment CB I. The total number of amino acid residues of fragment CB I accounted for 140 (54%) out of 260 residues in the Ala chain of ricin D.     

Site-directed mutagenesis of cysteine residues of large neutral amino acid transporter LAT1

The large neutral amino acid transporter type 1, LAT1, is the principal neutral amino acid transporter expressed at the blood-brain barrier (BBB). Owing to the high affinity (low K_m) of the LAT1 isoform, BBB amino acid transport in vivo is very sensitive to transport competition effects induced by hyperaminoacidemias, such as phenylketonuria. The low K_m of LAT1 is a function of specific amino acid residues, and the transporter is comprised of 12 phylogenetically conserved cysteine (Cys) residues. LAT1 is highly sensitive to inhibition by inorganic mercury, but the specific cysteine residue(s) of LAT1 that account for the mercury sensitivity is not known. LAT1 forms a heterodimer with the 4F2hc heavy chain, which are joined by a disulfide bond between Cys¹⁶⁰ of LAT1 and Cys¹¹⁰ of 4F2hc. The present studies use site-directed mutagenesis to convert each of the 12 cysteines of LAT1 and each of the 2 cysteines of 4F2hc into serine residues. Mutation of the cysteine residues of the 4F2hc heavy chain of the hetero-dimeric transporter did not affect transporter activity. The wild type LAT1 was inhibited by HgCl₂ with a K_i of 0.56 ± 0.11 μM. The inhibitory effect of HgCl₂ for all 12 LAT1 Cys mutants was examined. However, except for the C439S mutant, the inhibition by HgCl₂ for 11 of the 12 Cys mutants was comparable to the wild type transporter. Mutation of only 2 of the 12 cysteine residues of the LAT1 light chain, Cys⁸⁸ and Cys⁴³⁹, altered amino acid transport. The V_max was decreased 50% for the C88S mutant. A kinetic analysis of the C439S mutant could not be performed because transporter activity was not significantly above background. Confocal microscopy showed the C439S LAT1 mutant was not effectively transferred to the oocyte plasma membrane. These studies show that the Cys⁴³⁹ residue of LAT1 plays a significant role in either folding or insertion of the transporter protein in the plasma membrane.     

A mouse immunoglobulin heavy chain deletion mutant: isolation of a cDNA clone and sequence analysis of the mRNA

The mouse cell line IF2 secretes an immunoglobulin heavy chain lacking the CH1 domain. We have isolated and characterised a recombinant plasmid containing cDNA copies of the IF2 mutant mRNA. The cloned sequence extends from the nucleotides coding for amino acid 96 in the variable region through 100 nucleotides of untranslated region at the 3' end. The sequence of the cDNA insert reveals no discontinuity at the variable-hinge region junction, the site of the CH1 deletion. Experiments employing direct priming on the poly(A) tail of the IF2 heavy chain mRNA suggest that the 3' end of the cDNA clone (sequence C-C-C-T-G-C) is also the 3' end of the mRNA.     

Evidence for noncontiguous variable and constant region genes in both germ line and myeloma DNA.

A study has been made of the hybridization of mouse light chain cDNA to restriction enzyme digests of DNA. DNA was digested with B. st (specificity GGATCC) and fractionated on preparative agarose gels for hybridization analysis. Experiments with liver or kidney DNA yielded two peaks of hybridization with V+C cDNA corresponding to the C_κ gene and to the germ line V gene homologous to the MOPC21 V gene. Since there is no site for digestion by B. st within the MOPC21 V or C genes, this result shows that the germ line DNA carries separately the V²¹ and C_κ genes.The hybridization profiles of two different myeloma DNAs (MOPC21 and AdjPC5) differed from those of the germ line DNA. In both myelomas, only one hybridization peak was observed and no peaks corresponding to the germ line pattern were seen. The new pattern of hybridization implies that the events involved in maturation of antibody-producing cells includes rearrangement of the V and C genes.To study whether this proposed rearrangement of DNA results in contiguous V and C genes in producing cells, discrete V+C cDNA size classes (prepared with MOPC21 mRNA) were hybridized to both unfractionated restriction digested MOPC21 DNA and to the partially purified L chain gene of MOPC21 DNA. The length of the cDNA rendered resistant to single-strand-specific S₁ nuclease was determined. In no case was the full length of V+C cDNA protected from nuclease; instead, a fragment of about 290 bases (C region length) plus smaller fragments were generated. These results indicate that the rearrangement of L chain genes, which seems to occur in myeloma cells, may well not produce contiguous V and C genes in the DNA.     

Amino acid sequence of the VH region of a human myeloma immunoglobulin (IgG New).

The amino acid sequence of the heavy-chain variable region of the human immunoglobulin. New has been determined. Since the amino terminus of the heavy chain was blocked, the sequence of residues 1-69 was established by digesting the appropriate CNBr fragment separately with trypsin, chymotrypsin, and thermolysin and sequencing the resulting peptides. The region from residues 70 to 120 was present in another CNBr fragment which was submitted directly to automatic Edman degradation. The result of this experiment extended the sequence to residue 100. The primary structure of the remaining portion of the VH region was determined by automatic Edman degradation of a lysine-blocked tryptic peptide derived from this region which included residues 98-214. The sequence of the VH region of New corresponds most closely to VH sequences of proteins in the VH II subgroup. This primary structure makes it possible to construct a model from the high-resolution electron-density map of protein New.     

Further studies on o(2)-resistant photosynthesis and photorespiration in a tobacco mutant with enhanced catalase activity

The increase in net photosynthesis in M₄ progeny of an O₂-resistant tobacco (Nicotiana tabacum) mutant relative to wild-type plants at 21 and 42% O₂ has been confirmed and further investigated. Self-pollination of an M₃ mutant produced M₄ progeny segregating high catalase phenotypes (average 40% greater than wild type) at a frequency of about 60%. The high catalase phenotype cosegregated precisely with O₂-resistant photosynthesis. About 25% of the F₁ progeny of reciprocal crosses between the same M₃ mutant and wild type had high catalase activity, whether the mutant was used as the maternal or paternal parent, indicating nuclear inheritance. In high-catalase mutants the activity of NADH-hydroxypyruvate reductase, another peroxisomal enzyme, was the same as wild type. The mutants released 15% less photorespiratory CO₂ as a percent of net photosynthesis in CO₂-free 21% O₂ and 36% less in CO₂-free 42% O₂ compared with wild type. The mutant leaf tissue also released less ¹⁴CO₂ per [1-¹⁴C]glycolate metabolized than wild type in normal air, consistent with less photorespiration in the mutant. The O₂-resistant photosynthesis appears to be caused by a decrease in photorespiration especially under conditions of high O₂ where the stoichiometry of CO₂ release per glycolate metabolized is expected to be enhanced. The higher catalase activity in the mutant may decrease the nonenzymatic peroxidation of keto-acids such as hydroxypyruvate and glyoxylate by photorespiratory H₂O₂.     

Biochemical studies on the H-2K mutant B6.C-H-2 bm10

The H-2K glycoprotein from the MHC mutant bm10 was analyzed biochemically to determine where primary structural differences distinguished it from the parental standard molecule, K^b. Comparative peptide maps showed differences in two peptides known to be part of the parental CNBr fragment spanning amino acids 139 to 228. Partial sequence analyses of CNBr fragments and tryptic peptides identified two tightly clustered amino acid substitutions at amino acids 165 (Val to Met) and 173 (Lys to unknown). The substitutions in bm10 represent the most carboxy-terminal substitutions characterized in the K^b molecules of the spontaneous, histogenically active H-2 mutants.     

A dominant mutation in Escherichia coli OmpR lies within a domain which is highly conserved in a large family of bacterial regulatory proteins

Summary We have fortuitously created an in-frame insertion mutation in the cloned ompR gene of Escherichia coli in the course of an experiment involving linker insertion mutagenesis. According to the DNA sequence, the mutant protein has an insertion at the 53rd amino acid residue, which replaced the original valine, with the sequence Ala-Leu-Glu. The expression level of the mutant protein, OmpRX6, in a minicell system, is similar to that of the wild-type protein and the size of the mutant is slightly larger than the wild type by approxiately 300 daltons. This mutant was completely unable to activate porin expression as the wildtype does, and in addition, this phenotype was shown to be dominant over the wild type. Comparison of the amino acid sequence of OmpRX6 with those of a family of homologous bacterial regulatory proteins revealed that the mutation lies in a domain which is highly conserved among these proteins.     

Three amino acids in the D2 dopamine receptor regulate selective ligand function and affinity

The D₂ dopamine receptor is an important therapeutic target for the treatment of psychotic, agitated, and abnormal behavioral states. To better understand the specific interactions of subtype‐selective ligands with dopamine receptor subtypes, seven ligands with high selectivity (>120‐fold) for the D₄ subtype of dopamine receptor were tested on wild‐type and mutant D₂ receptors. Five of the selective ligands were observed to have 21‐fold to 293‐fold increases in D₂ receptor affinity when three non‐conserved amino acids in TM2 and TM3 were mutated to the corresponding D₄ amino acids. The two ligands with the greatest improvement in affinity for the D₂ mutant receptor [i.e., 3‐{[4‐(4‐iodophenyl) piperazin‐1‐yl]methyl}‐1H‐pyrrolo[2,3‐b]pyridine (L‐750,667) and 1‐[4‐iodobenzyl]‐4‐[N‐(3‐isopropoxy‐2‐pyridinyl)‐N‐methyl]‐aminopiperidine (RBI‐257)] were investigated in functional assays. Consistent with their higher affinity for the mutant than for the wild‐type receptor, concentrations of L‐750,667 or RBI‐257 that produced large reductions in the potency of quinpirole’s functional response in the mutant did not significantly reduce quinpirole’s functional response in the wild‐type D₂ receptor. In contrast to RBI‐257 which is an antagonist at all receptors, L‐750,667 is a partial agonist at the wild‐type D₂ but an antagonist at both the mutant D₂ and wild‐type D₄ receptors. Our study demonstrates for the first time that the TM2/3 microdomain of the D₂ dopamine receptor not only regulates the selective affinity of ligands, but in selected cases can also regulate their function. Utilizing a new docking technique that incorporates receptor backbone flexibility, the three non‐conserved amino acids that encompass the TM2/3 microdomain were found to account in large part for the differences in intermolecular steric contacts between the ligands and receptors. Consistent with the experimental data, this model illustrates the interactions between a variety of subtype‐selective ligands and the wild‐type D₂, mutant D₂, or wild‐type D₄ receptors.     

Amino acid sequence of the Bb fragment from complement Factor B. Sequence of the major cyanogen bromide-cleavage peptide (CB-II) and completion of the sequence of the Bb fragment.

The amino acid sequence of peptide CB-II, the major product (mol.wt. 30 000) of CNBr cleavage of fragment Bb from human complement Factor B, is given. The sequence was obtained from peptides derived by trypsin cleavage of peptide CB-II and clostripain digestion of fragment Bb. Cleavage of two Asn-Gly bonds in peptide CB-II was also found useful. These results, along with those presented in the preceding paper [Gagnon & Christie (1983) Biochem. J. 209, 51-60], yield the complete sequence of the 505 amino acid residues of fragment Bb. The C-terminal half of the molecule shows strong homology of sequence with serine proteinases. Factor B has a catalytic chain (fragment Bb) with a molecular weight twice that of proteinases previously described, suggesting that it is a novel type of serine proteinase, probably with a different activation mechanism.     

Secretion of a lambda 2 immunoglobulin chain is prevented by a single amino acid substitution in its variable region

We have studied two derivatives of the IgA (lambda 2) secreting myeloma cell line MOPC315:MOPC315.26, which produces and secretes a lambda 2 light chain, and MOPC315.37, which produces but does not secrete the lambda 2 chain. It has been reported that the only alteration in the MOPC315-37 lambda 2 chain is located in the variable region (Mosmann and Williamson, (1980) Cell 20, 283-292). In order to determine the nature of this alteration, we cloned the fragment of the chromosome containing the rearranged lambda 2 gene from both the nonsecreting variant MOPC315-37 and the normal lambda 2-secreting parent MOPC315-26 and determined their nucleotide sequence. We found that the nucleotide sequences coding for the leader peptide and for the constant region of the lambda 2 chain were identical in the secretor and nonsecretor. The sequences of the variable region differed at a single base pair corresponding to the first nucleotide in the codon for amino acid number 15. MOPC315-26 has a G in this position creating the codon GGT which codes for glycine, and MOPC315-37 has a C in this position creating the codon CGT which codes for arginine. Thus, we have demonstrated that a single amino acid substitution of a neutral amino acid, glycine, for a positively charged amino acid, arginine, results in the failure of a protein to be secreted.     

Two homogeneous myosins in body-wall muscle of Caenorhabditis elegans

Myosin purified from the body-wall muscle-defective mutant E675 of the nematode. Caenorhabditis elegans, has heavy chain polypeptides which can be distinguished on the basis of molecular weight. On SDS-polyacrylamide gels, bands are found at 210,000 and 203,000 daltons. This is in contrast to myosin from the wild-type, N2, which has a single heavy chain band at 210,000 daltons. Both heavy chains of E675 are found in body-wall muscle (Epstein, Waterston and Brenner, 1974).When native myosin from E675 is fractionated on hydroxyapatite, it is separated into myosin containing predominantly one or the other molecular weight heavy chain and myosin containing a mixture of the heavy chains. Comparison of the CNBr fragments of myosin that contains predominantly 210,000 dalton heavy chains with those of myosin that contains predominantly 203,000 dalton heavy chains reveals multiple differences. These differences are not explained by the difference in molecular weight of the heavy chains, but may be explained if each type of heavy chain is the product of a different structural gene. Furthermore, because there are fractions which exhibit >80% 210,000 or >80% 203,000 dalton heavy chain, there is myosin which is homogeneous for each of the heavy chains.Although N2 myosin has only a single molecular weight heavy chain, it too is fractionated by hydroxyapatite. By comparing the CNBr fragments of different myosin fractions, we show that N2, like E675, has two kinds of heavy chains.E190, a body-wall muscle-defective mutant in the same complementation group as E675, is lacking the myosin heavy chain affected by the e675 mutation. This property has allowed us to determine by co-purification of labeled E190 myosin in the presence of excess, unlabeled E675 myosin that most, if not all, of the myosin that contains two different molecular weight heavy chains is due to the formation of complexes between homogeneous myosins and not to a heterogeneous myosin.     

Carbon Partitioning in a Flaveria linearis Mutant with Reduced Cytosolic Fructose Bisphosphatase

Oxygen sensitivity and partitioning of carbon was measured in a mutant line of Flaveria linearis that lacks most of the cytosolic fructose-1,6-bisphosphatase found in wild-type lines. Photosynthesis of leaves of the mutant line was nearly insensitive to O₂, as found before. The mutant plants partitioned 2.5 times less carbon into sucrose than the wild type in a pulse chase experiment, with the extra carbon going mainly to starch but also to amino acids. From 10 to 50 min postlabeling, radioactivity chased out of the amino acid fraction to starch in both lines. In the middle of the light period, starch grains were larger in the mutant than in the wild type and covered 30% of the chloroplast area as seen with an electron microscope. Starch grains were found in both mesophyll and bundle sheath chloroplasts in both lines in these C₃-C₄ intermediate plants. At the end of the dark period, the starch levels were considerably reduced from what they were in the middle of the light in both lines. The concentration of sucrose was higher in the mutant line despite the lack of cytosolic fructose-1,6-bisphosphatase. The amino acid fraction accounted for about 30% of all label following a 10-min chase period. In the mutant line, most of the label was in the glycine + serine fraction, with 10% in the alanine fraction. In wild-type leaves, 35% of the label in amino acids was in alanine. These results indicate that this mutant survives the reduced cytosolic fructose-1,6-bisphosphatase activity by partitioning more carbon to starch and less to sucrose during the day and remobilizing the excess starch at night. However, these results raise two other questions about this mutant. First, why is the sucrose concentration high in a plant that partitions less carbon to sucrose, and second, why is alanine heavily labeled in the wild-type plants but not in the mutant plants?     

Structural mutations in a mouse immunoglobulin light chain resulting in failure to be secreted

Two nonsecreting clones of MOPC 315 mouse myeloma cells were compared with a clone of the same cell line secreting λ light chains. All three clones synthesized λ chains but no detectable heavy chains. The two mutant clones which failed to secrete λ chains both synthesized an altered λ chain. The structural alterations were demonstrated by two independent methods for each mutant, and in each case were located in one peptide derived by cyanogen bromide cleavage. In one clone, the alteration was located in the N terminal 87 amino acids of the protein, and was thus present in the variable region of the light chain. In the other clone, the alteration was located between residues 88 and 175. Light chain precursors, and not mature light chains, were synthesized in a cell-free translation system from polyribosomes derived from each of the three cell lines. The structural alterations characteristic of the two mutant clones were also present on the λ chains synthesized in vitro. These results suggest that the mutant light chains were synthesized as precursor molecules and cleaved in vivo, and that the block in secretion occurred at some stage after precursor cleavage. For the MOPC 315 light chain, the synthesis and cleavage of a precursor polypeptide sequence may be necessary, but does not appear to be sufficient, for subsequent secretion of the protein.