Conjugation of aspartic acid with 4-bromophenylacetic acid,an auxin analogue of aspartic acid

Tobacco mesophyll protoplasts conjugate the auxins indoleacetic acid and naphthaleneacetic acid with aspartic acid very efficiently. This conjugation was found to be correlated with the toxicity of these molecules to protoplast-derived cells grown at low densities. Among a series of halogenated phenylacetic acids, 4-bromophenylacetic was toxic to cells grown at low densities although not able to stimulate proliferation at high cell densities, as opposed to indoleacetic acid and naphthaleneacetic acid. [¹⁴C-car☐yl]-4-bromophenylacetic acid was conjugated with aspartic acid by tobacco protoplasts. Although 4-bromophenylacetic acid is not an auxin, this molecule shares with auxins some of their properties.     

Immunostimulant properties of aspartic acid

The experiments on mice have shown that aspartic acid and aspartic acid-containing functionally different agents (panangin, thymopentin, pentagastrin) promoted the in vitro differentiation of bone marrow T-precursors into T-lymphocytes and stimulated the in vivo immune response to SRBC. At the same time aspartic acid and panangin had no effect on the immune response to thymus-independent Vi-antigen.     

14-Dehydro-19-nortestosterone and its 7 -methyl derivative

14-Dehydro-19-nortestosterone and its 7α-methyl derivative were synthesized. The former was found to be approximately 100 and the latter 1000 times as active as testosterone in chick comb (local application) assays. In rat assays (subcutaneous), 14-dehydro-19-nortestosterone was approximately one-half as active as, or equal to testosterone in the ventral prostate or levator ani assays respectively, whereas its 7α-methyl derivative still retained its high potency (100 times as active as testosterone) in either type of assay.     

Microwave-assisted reaction of glycosylamine with aspartic acid

The synthesis of N-protected glycosyl amino acids from amines has been investigated and it was found that, under microwave conditions, glycosylamines could be hydrolyzed leading to new products containing a glycosyl ester linkage. The efficiency of the microwave-induced glycosylation of aspartic acid was studied comparing the microwave activity between amide and ester bond formation. Different sugar moieties have been employed to demonstrate the simple and reproducible coupling methodology. New glycosyl ester compounds were further characterized by NMR spectroscopy.     

Is aspartic acid regulator of hemopoiesis?]

The effect of aspartic acid on myelopoiesis was examined. A method of bone marrow cultivation was used in diffusion chambers in vivo. We found that injection of 1 x 10(-4) g/kg aspartic acid to intact rats during 5 days resulted in increase of cloning efficiency of granulocyte-progenitor cells by 24 per cent and growth of cluster/colony-forming unit fibroblastic. On the basis of these data we came to the conclusion that aspartic acid acts directly on hemopoietic cells and stromal system.     

Effects of aspartic acid on skate electroreceptors

The effects of L-aspartic acid (L-ASP) on spontaneous and evoked activity in afferent nerve fibers were investigated by perfusing the basal membrane of sea skate electroreceptors (the ampullae of Lorenzini) with this substance. It was found that perfusion with physiological saline containing L-ASP exerted a primarily excitatory effect on afferent activity (threshold concentration: 10^–7 M). When synaptic transmission was blocked by magnesium ions, activity was restored in the afferent fibers if L-ASP was added to the solution and spike activity persisted for longer; this would imply the presence of desensitizing processes in the postsynaptic receptors of the ampullae. Finding would lead to the conclusion that L-ASP and L-glutamate fulfill a set of criteria for likely neurotransmitters in the ampullae of Lorenzini.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 19, No. 1, pp. 61–67, January–February, 1987.