Determination for inflorescence development is a stable state,separable from determination for flower development in Pisum sativum L. buds

Terminal meristems of Pisum sativum (garden pea) transit from vegetative to inflorescence development, and begin producing floral axillary meristems. Determination for inflorescence development was assessed by culturing excised buds and meristems. The first node of floral initiation (NFI) for bud expiants developing in culture and for adventitious shoots forming on cultured meristems was compared with the NFI of intact control buds. When terminal buds having eight leaf primordia were excised from plants of different ages (i.e., number of unfolded leaves) and cultured on 6-benzylaminopurine and kinetin-supplemented medium, the NFI was a function of the age of the source plant. By age 3, all terminal buds were determined for inflorescence development. Determination occurred at least eight nodes before the first axillary flower was initiated. Thus, the axillary meristems contributing to the inflorescence had not formed at the time the bud was explanted. Similar results were obtained for cultured axillary buds. In addition, meristems excised without leaf primordia from axillary buds three nodes above the cotyledons of age-3 plants gave rise to adventitious buds with an NFI of 8.3 ±0.3 nodes. In contrast seed-derived plants had an NFI of 16.5 ±0.2. Thus cells within the meristem were determined for inflorescence development. These findings indicate that determination for inflorescence development in P. sativum is a stable developmental state, separable from determination for flower development, and occurring prior to initiation of the inflorescence at the level of meristems.     

Synchronized synthesis and intracellular transport of serum albumin and apolipoprotein B in cultured rat hepatocytes as studied by double immunofluorescence

Synthesis and intracellular transport of two secretory proteins, serum albumin (SA) and apolipoprotein B (apo B) have been synchronized in primary cultures of normal rat hepatocytes to make possible immunocytochemical study of the transport pathway. Under appropriate conditions of cycloheximide treatment, synthesis of new protein was inhibited and, by double immunofluorescent labeling, the cells were found to be largely depleted of the SA and apo B previously synthesized. Re-initiation of protein synthesis led to sequential appearance of SA and apo B, first in the endoplasmic reticulum, then in the Golgi complex, and finally at the cell surface. These results indicate that it should be feasible to use this cell system for high-resolution investigation of the sequence of structures involved in intracellular transport of SA and apo B by corresponding immunolabeling experiments as observed by electron microscopy.     

alpha-Carboxyl-linked glutamates in the folylpolyglutamates of Escherichia coli

Folate cofactors in most cells contain polyglutamate side chains, which since the late 1940s have been assumed to be linked via their gamma-COOH groups. We report here an investigation of the structure of the polyglutamate chain attached to the folates of Escherichia coli. Folates were extracted from E. coli grown with [7-14C] p-aminobenzoate and cleaved to p-aminobenzoyl polyglutamates of varying chain lengths (pAB(Glu)n) by the method of Foo et al. (Foo, S. K., Cichowicz, D. J., and Shane, B. (1980) Anal. Biochem. 107, 109-115). The pAB(Glu)n derived from E. coli did not co-chromatograph with chemically synthesized pAB(gamma-Glu)n-Glu on several high performance liquid chromatography (HPLC) systems, except for the triglutamate which did elute with pAB(gamma-Glu)2-Glu. E. coli-derived pAB(Glu)3-8 were purified by HPLC on C18 columns eluted with acetonitrile/trifluoroacetic acid, and the structures were determined through mass spectrometry, chiral amino acid analysis, and peptidase digestion experiments. Molecular weight determinations on the methyl ester derivatives of E. coli-derived pAB(Glu)n by liquid secondary ion mass spectrometry and sequence analysis using collision-activated dissociation on a tandem mass spectrometer confirmed the structures as pAB(Glu)3-8. Chiral HPLC of hydrolyzed and dansylated E. coli-derived materials, on a beta-cyclodextrin column, identified the glutamate as the L-enantiomer. pAB(Glu)n were digested with carboxypeptidase Y, which specifically cleaved glutamates linked at their alpha-carboxyls; E. coli-derived pAB(Glu)4-8 (but not synthetic pAB(gamma-Glu1-6-Glu) were sequentially digested to pAB(gamma-Glu)2-Glu. Thus, in E. coli folylpolyglutamates, glutamate residues 4-8 were each linked to the polyglutamate chain at the alpha-carboxyl of the preceding glutamate.     

Molecular cloning and characterization of the Endo B cytokeratin expressed in preimplantation mouse embryos

A cDNA clone of a keratin-related, intermediate filament protein, designated Endo B, was constructed from size-fractionated parietal endodermal mRNA and characterized. The 1466-nucleotide cDNA insert contains an open reading frame of 1272 nucleotides that would result in 5' and 3' noncoding sequences of 54 and 60 nucleotides, respectively. The predicted amino acid composition, molecular weight (47,400), and peptide pattern correlate well with data obtained on the isolated protein. The predicted amino acid sequence fits easily into the general domain structure suggested for all intermediate filament proteins with a unique amino-terminal head domain, a large conserved central domain of predominantly alpha-helical structure, and a relatively unique carboxyl-terminal or tail domain. Over the entire molecule, Endo B is 43% identical with human 52-kDa epidermal type I keratin. However, over two of the three regions contained in the central domain that are predicted to form coiled-coil structures, the Endo B is 54-68% identical with other type I keratin sequences. This homology, along with the presence of the completely conserved sequence DNARLAADDFR-KYE, which is found in all type I keratins, permits the unambiguous identification of Endo B as a type I keratin. Comparison of the Endo B sequence to other intermediate filament proteins reveals 22 residues which are identical in all intermediate filament proteins regardless of whether filament formation requires only one type of protein subunit (vimentin, desmin, glial fibrillar acidic protein, or a neurofilament protein) or two dissimilar types (type I and type II keratins). Endo B mRNA was detectable in RNA isolated from F9 cells treated with retinoic acid for 48 h. Approximately three to five genes homologous to Endo B were detected in the mouse genome.     

Structure and expression of two porcine genomic clones encoding class I MHC antigens

Two nonallelic porcine class I MHC (SLA) genes have been isolated and characterized. Both genes are expressed in mouse L cells, directing the synthesis of class I SLA molecules that carry common monomorphic determinants but are serologically distinct. The corresponding DNA sequences have been determined. The organization of both of these genes is similar to that of other class I genes: a leader exon, three exons encoding extracellular domains, a transmembrane exon, and three intracytoplasmic exons. The two genes are highly homologous in both exon and intron segments, with average homologies of 88% and 80%, respectively. Nucleotide changes in exon 2 are clustered, whereas those in the other exons are dispersed throughout. Comparison of the swine DNA sequences with class I genes from other species reveals a generally high conservation of exons 2, 3, 4, and 6 with lower homology in the remaining protein-encoding domains. Introns are markedly less well conserved, although moderate homology is found between swine and human class I MHC genes in both introns and 3' flanking regions. Taken together with comparisons of the deduced protein sequences, these data indicate an order of swine greater than human greater than rabbit greater than mouse in the relationship of class I genes.     

Fatty aldehyde dehydrogenases in Acinetobacter sp. strain HO1-N: role in hexadecanol metabolism

The role of fatty aldehyde dehydrogenases (FALDHs) in hexadecane and hexadecanol metabolism was studied in Acinetobacter sp. strain HO1-N. Two distinct FALDHs were demonstrated in Acinetobacter sp. strain HO1-N: a membrane-bound, NADP-dependent FALDH activity induced 5-, 15-, and 9-fold by growth on hexadecanol, dodecyl aldehyde, and hexadecane, respectively, and a constitutive, NAD-dependent, membrane-localized FALDH. The NADP-dependent FALDH exhibited apparent Km and Vmax values for decyl aldehyde of 5.0, 13.0, 18.0, and 18.3 microM and 537.0, 500.0, 25.0, and 38.0 nmol/min in hexadecane-, hexadecanol-, ethanol-, palmitate-grown cells, respectively. FALDH isozymes ald-a, ald-b, and ald-c were demonstrated by gel electrophoresis in extracts of hexadecane- and hexadecanol-grown cells. ald-a, ald-b, and ald-d were present in dodecyl aldehyde-grown cells, while palmitate-grown control cells contained ald-b and ald-d. Dodecyl aldehyde-negative mutants were isolated and grouped into two phenotypic classes based on growth: class 1 mutants were hexadecane and hexadecanol negative and class 2 mutants were hexadecane and hexadecanol positive. Specific activity of NADP-dependent FALDH in Ald21 (class 1 mutant) was 85% lower than that of wild-type FALDH, while the specific activity of Ald24 (class 2 mutant) was 55% greater than that of wild-type FALDH. Ald21R, a dodecyl aldehyde-positive revertant able to grow on hexadecane, hexadecanol, and dodecyl aldehyde, exhibited a 100% increase in the specific activity of the NADP-dependent FALDH. The oxidation of [3H]hexadecane byAld21 yielded the accumulation of 61% more fatty aldehyde than the wild type, while Ald24 accumulated 27% more fatty aldehyde, 95% more fatty alcohol, and 65% more wax ester than the wild type. This study provides genetic and physiological evidence for the role of fatty aldehyde as an essential metabolic intermediate and NADP-dependent FALDH as a key enzyme in the dissimilation of hexadecane, hexadecanol, and dodecyl aldehyde in Acinetobactor sp. strain HO1-N.     

Alcohol dehydrogenases in Acinetobacter sp. strain HO1-N: role in hexadecane and hexadecanol metabolism.

Multiple alcohol dehydrogenases (ADH) were demonstrated in Acinetobacter sp. strain HO1-N. ADH-A and ADH-B were distinguished on the basis of electrophoretic mobility, pyridine nucleotide cofactor requirement, and substrate specificity. ADH-A is a soluble, NAD-linked, inducible ethanol dehydrogenase (EDH) exhibiting an apparent Km for ethanol of 512 microM and a Vmax of 138 nmol/min. An ethanol-negative mutant (Eth1) was isolated which contained 6.5% of wild-type EDH activity and was deficient in ADH-A. Eth1 exhibited normal growth on hexadecane and hexadecanol. A second ethanol-negative mutant (Eth3) was acetaldehyde dehydrogenase (ALDH) deficient, having 12.5% of wild-type ALDH activity. Eth3 had threefold-higher EDH activity than the wild-type strain. ALDH is a soluble, NAD-linked, ethanol-inducible enzyme which exhibited an apparent Km for acetaldehyde of 50 microM and a Vmax of 183 nmol/min. Eth3 exhibited normal growth on hexadecane, hexadecanol, and fatty aldehyde. ADH-B is a soluble, constitutive, NADP-linked ADH which was active with medium-chain-length alcohols. Hexadecanol dehydrogenase (HDH), a soluble and membrane-bound, NAD-linked ADH, was induced 5- to 11-fold by growth on hexadecane or hexadecanol. HDH exhibited apparent Kms for hexadecanol of 1.6 and 2.8 microM in crude extracts derived from hexadecane- and hexadecanol-grown cells, respectively. HDH was distinct from ADH-A and ADH-B, since HDH and ADH-A were not coinduced; Eth1 had wild-type levels of HDH; and HDH requires NAD, while ADH-B requires NADP. NAD- and NADP-independent HDH activity was not detected in the soluble or membrane fraction of extracts derived from hexadecane- or hexadecanol-grown cells. NAD-linked HDH appears to possess a functional role in hexadecane and hexadecanol dissimilation.