Jeffrey David Hulmes

Molecular characterization of interleukin 12

Interleukin 12 (IL-12), formerly known as cytotoxic lymphocyte maturation factor and natural killer cell stimulatory factor, is a cytokine secreted by a human B lymphoblastoid (NC-37) cell line when induced in culture with phorbol ester and calcium ionophore. This factor has been purified to homogeneity and shown to synergize with low concentrations of interleukin 2 in causing the induction of lymphokine-activated killer cells. In addition, purified IL-12 stimulated the proliferation of human phytohemagglutinin-activated lymphoblasts by itself and exerted additive effects when used in combination with suboptimal amounts of interleukin 2. The protein is a heterodimer composed of a 40- and a 35-kDa subunit. Amino acid sequence analysis confirmed predicted sequences from the cloned cDNAs of each subunit. Chemical and enzymatic deglycosylation of the heterodimer demonstrated that the 40- and 35-kDa subunits contain 10 and 20% carbohydrate, respectively. Structural analysis of IL-12 using site-specific chemical modification revealed that intact disulfide bonds are essential for bioactivity. The 40-kDa subunit of IL-12 was identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and confirmed by immunoblotting as being present in NC-37 cell supernatant solutions in relatively large amounts uncomplexed to the 35-kDa subunit. Previously it had been shown that the 40-kDa subunit alone does not cause the proliferation of activated human T lymphocytes or enhance the cytolytic activity of human natural killer cells. However, results obtained by site-specific chemical modification suggesting that a tryptophan residue is at or near the active site of IL-12 may imply a direct role of the subunit in interacting with the IL-12 receptor. These data may support the recent proposal (D.P. Gearing and D. Cosman (1991) Cell 66, 9-10) that IL-12 consists of a complex of cytokine and soluble receptor.

Guinea pig has a unique mammalian VIP

Mammalian vasoactive intestinal peptide (VIP) has been reported to be identical in four species. This report describes the extraction of guinea pig (GP) intestinal VIP, its purification and sequence. Frozen intestines were extracted in five volumes of methanol and the methanol cakes reextracted with acid. VIP in the acid extract was concentrated onto ion-exchange cellulose and was brought to final purity through a series of HPLC steps. GP VIP differs from other mammalian VIPs by four amino acid substitutions: (sequence in text) This is further evidence that the GP gastroenteropancreatic axis has a unique evolutionary separation from other mammals.

Purification and sequencing of a rat intestinal 22 amino acid C-terminal CCK fragment.

Fractionation on Sephadex G50 gel of methanol extracts of rat intestine revealed two molecular forms of cholecystokinin (CCK) of about equal immunopotency: one form has an elution volume between CCK33 and CCK12; the other elutes in the salt region as does authentic CCK8. Purification and sequencing have demonstrated that the smaller molecular form is CCK8 with a sequence identical to the pork and sheep CCK8s that had previously been sequenced. Purification and sequencing of the larger molecular form reveals that it is a 22 amino acid C-terminal CCK fragment identical with pig CCK22 except that glycine instead of serine is present at the nineteenth residue from the C-terminus. This sequence is consistent with that predicted by cloned cDNA encoding preprocholecystokinin from a rat medullary thyroid carcinoma. CCK22 has not previously been reported to be a prominent molecular form in either pig or dog intestines.

Unique cholecystokinin peptides isolated from guinea pig intestine

Fractionation on Sephadex G50 gel of methanol extracts of guinea pig intestine reveals two molecular forms of cholecystokinin (CCK) of about equal abundance. One elutes at the position of CCK8 while the other elutes at a position intermediate between CCK33 and CCK8. Purification and sequencing of these peptides identify them as CCK8 and CCK22, respectively. Guinea pig CCK8 differs from other mammalian CCK octapeptides isolated thus far in that there is a valine substituted for methionine at position 6 from the C-terminus. In addition to the substitution in CCK8, serine is substituted for asparagine in position 22, glycine for serine in position 19, and asparagine for serine in position 15 from the C-terminus compared to the pig sequence. HPLC separation on a C18 column yields two peaks each of CCK8 and of CCK22 in pig intestinal tissue obtained from a commercial supplier. The two CCK8 peptides have identical amino acid sequences as do the two CCK22 peptides. The CCK22 peptides are equally bioactive in the guinea pig pancreatic acinar cell assay but are about 10-fold less potent than synthetic CCK8(s). One of the guinea pig CCK8 peptides is fully bioactive whereas the other is about 50-fold less potent compared to synthetic CCK8(s).

Cholecystokinin octapeptides purified from chinchilla and chicken brains.

Cholecystokinin octapeptides (CCK8s) have been purified from methanol extracts of 30 chinchilla and 50 chicken brains containing 9.3 nmol and 8.5 nmol of the peptides respectively. Immunoreactive CCK was concentrated on a DEAE trisacryl column and purification effected by two successive HPLC steps. The peptides were each shown to have a sulfated tyrosine. The sequences of the two peptides are compared with the corresponding CCK8s of pig and guinea pig (GP). Chinchilla & GP: D Y V G W M D F; Chicken & pig: D Y M G W M D F. Since chinchilla insulin resembles other mammalian insulins more than does GP insulin, it is of particular interest that the CCK8s of these two species are identical and raises the question as to whether other brain-gut peptides of the chinchilla, which is a New World mammal as is the GP, would resemble those of the GP or the corresponding peptides of Old World mammals.

Purification of dog VIP from a single animal.

VIP, a potent vasodilator peptide, is reported to be identical in pig, cow, human and rat but to differ in four amino acids in chicken. This report describes the purification of dog VIP from the small intestine of a single animal. The purification method is based on tissue extraction with a sequence of organic solvents. The extracted VIP is concentrated onto cation-exchange cellulose and brought to purity by three HPLC steps. A 30% final yield of pure VIP was obtained from the original extract. Dog VIP was found to have the following sequence: His-Ser-Asp-Ala-Val-Phe-Thr-Asp-Asn-Tyr-Thr-Arg-Leu-Arg-Lys-Gln-Met-Ala -Val-Lys-Lys-Tyr-Leu-Asn-Ser-Ile-Leu-Asn. Thus the amino acid sequence of dog VIP is identical with all the mammalian VIPs which have been reported. This suggests that a high degree of conservation throughout the molecule may be required for VIP bioactivity.

The use of fluorescamine as a detection reagent in protein microcharacterization

With recent advances in protein microchemistry, compatible methods for the preparation and quantitation of proteins and peptides are required. Fluorescamine, a reagent which reacts with primary amino groups has been used successfully to detect amino acids, peptides, and proteins in various micromethods. This article discusses these methods which include (1) amino acid analysis of protein and peptide hydrolysates with postcolumn fluorescamine derivatization; (2) purification and characterization of proteins and peptides by reversed-phase HPLC with postcolumn fluorescamine derivatization; (3) purification of peptides by two-dimensional chromatography and electrophoresis on thin-layer cellulose with fluorescamine staining; and (4) electroblotting of protein bands from SDS-PAGE to glass fiber filters and polyvinylidene difluoride (PVDF) membranes with fluorescamine staining. In addition, this article also compares a postcolumn fluorescamine detection system with a UV detection system in the applications of amino acid analysis and reversed-phase HPLC protein/peptide analysis.

Structural analysis of recombinant soluble human interleukin-2 receptor primary structure, assignment of disulfide bonds and core IL-2 binding structure

A purified soluble and functional form of recombinant human interleukin-2 receptor, engineered and expressed in Chinese hamster ovary cells, was structurally characterized. The primary sequence of this 224 amino acid recombinant protein which lacks most of the carboxy-terminal transmembrane and cytoplasmic portions of the intact protein was established by sequence analyses. The disulfide bonds were assigned by comparative peptide mapping of the reduced and non-reduced peptide digests. As in the case of natural interleukin-2 receptor they occur between cysteines 3-147, 46-104, 131-163, and 28/30-59/61. Based on assignment of the disulfide bonds, a structural model of the interleukin-2 receptor for interleukin-2 binding is proposed.

Guinea pig pancreatic polypeptide: Structure and pancreatic content

Guinea pig (GP) pancreatic polypeptide (PP) has been purified from an acid-alcohol extract of 6 GP pancreata by a series of 3 HPLC steps. The sequence for GP PP as compared with that of beef and human is shown: (Sequence: see text). In a single GP pancreas weighing 2.4 g the total PP content was 1.0 nmol and the total glucagon content 61 nmol; in a single dog pancreas weighing 35 g the total PP was 385 nmol and the total glucagon 81 nmol. The relatively low content of PP in GP pancreas is consistent with the fact that the GP lacks a ventral pancreas, the region in which PP is found in highest concentration. The high glucagon content of GP pancreas is consistent with that reported in earlier studies.

Selective cleavage of polypeptides with trifluoroacetic acid: Applications for microsequencing

Cleavage of small polypeptides (less than 30 amino acid residues) by trifluoroacetic acid (TFA) under a variety of reaction conditions including time, temperature, TFA phase, and sample supports has been examined by N-terminal sequencing. Treatment with gas-phase TFA at room temperature will cleave polypeptide chains preferentially at the N-terminal side of serine and threonine residues. When liquid-phase TFA is used, additional cleavage at the C-terminal side of aspartic acid was detected. These procedures are applicable for directly treating samples immobilized on sequencer supports (glass fiber filters or polyvinylidene difluoride membranes) to verify the presence of a polypeptide with a blocked N-terminus as well as to obtain internal sequence data at subnanomole levels.