András Perczel

Natively unfolded tubulin polymerization promoting protein TPPP/p25 is a common marker of alpha-synucleinopathies

The novel basic, heat-stable tubulin polymerization promoting protein TPPP/p25 is associated with microtubules in vitro and can induce the formation of aberrant microtubule assemblies. We show by 1H-NMR spectroscopy that TPPP/p25 is natively unfolded. Antisera against peptide 186GKGKAGRVDLVDESG200NH2 (186-200) are highly specific to TPPP/p25. Immunohistochemistry and confocal microscopy demonstrates that TPPP/p25 is enriched in filamentous alpha-synuclein bearing Lewy bodies of Parkinsons (PD) and diffuse Lewy body disease (DLBD), as well as glial inclusions of multiple system atrophy (MSA). There is a correlation between TPPP/p25 and alpha-synuclein immunoreactivity in Western blot. In contrast, TPPP/p25 is not associated with abnormally phosphorylated tau in various inclusions of Picks disease (PiD), progressive supranuclear palsy (PSP), and corticobasal degeneration (CBD). However, electron microscopy confirms clusters of TPPP/p25 immunoreactivity along filaments of unstructured but not compact neurofibrillary tangles in Alzheimers disease (AD). TPPP/p25 seems to be a novel marker of alpha-synucleinopathies.

Metal ion-induced conformational changes of phosphorylated fragments of human neurofilament (NF-M) protein.

The NF-M subunit of human neurofilaments has a C-terminal repeating 13-mer sequence. The 13-mer (Lys-Ser-Pro-Val-Pro-Lys-Ser-Pro-Val-Glu-Glu-Lys-Gly) (NF-M13) and 17-mer (Glu-Glu-Lys-Gly)-(NF-M13) sequences were synthesized, as were both the mono- and diphosphorylated Ser species. Circular dichroism (c.d.) studies and c.d. titrations with Al3+ and Ca2+ were performed. The conformation of the phosphorylated and unphosphorylated material was random in water. Deconvolution of the c.d. spectra, in trifluoroethanol, of the untitrated samples yielded a high content of unordered structure, similar to the poly-L-proline II structure. Titration of the phosphorylated species with Al3+ or Ca2+ caused a surprising conformational change to occur, yielding a high content of beta-pleated sheet structure. A mechanism of metal binding to the phosphofragments is proposed which may be relevant to the formation of neurofibrillary tangles in Alzheimers disease.

Mutation-dependent recessive inheritance of NPHS2-associated steroid-resistant nephrotic syndrome

Monogenic disorders result from defects in a single gene. According to Mendels laws, these disorders are inherited in either a recessive or dominant fashion. Autosomal-recessive disorders require a disease-causing variant on both alleles, and according to our current understanding, their pathogenicities are not influenced by each other. Here we present an autosomal-recessive disorder, nephrotic syndrome type 2 (MIM 600995), in which the pathogenicity of an NPHS2 allele encoding p.Arg229Gln depends on the trans-associated mutation. We show that, contrary to expectations, this allele leads to a disease phenotype only when it is associated specifically with certain 3′ NPHS2 mutations because of an altered heterodimerization and mislocalization of the encoded p.Arg229Gln podocin. The disease-associated 3′ mutations exert a dominant-negative effect on p.Arg229Gln podocin but behave as recessive alleles when associated with wild-type podocin. Therefore, the transmission rates for couples carrying the disease-associated mutations and p.Arg229Gln may be substantially different from those expected in autosomal-recessive disorders.

Peptide models. XXXIII. Extrapolation of low-level Hartree-Fock data of peptide conformation to large basis set SCF, MP2, DFT, and CCSD(T) results. The Ramachandran surface of alanine dipeptide computed at various levels of theory

At the dawn of the new millenium, new concepts are required for a more profound understanding of protein structures. Together with NMR and X‐ray‐based 3D‐stucture determinations in silico methods are now widely accepted. Homology‐based modeling studies, molecular dynamics methods, and quantum mechanical approaches are more commonly used. Despite the steady and exponential increase in computational power, high level ab initio methods will not be in common use for studying the structure and dynamics of large peptides and proteins in the near future. We are presenting here a novel approach, in which low‐ and medium‐level ab initio energy results are scaled, thus extrapolating to a higher level of information. This scaling is of special significance, because we observed previously on molecular properties such as energy, chemical shielding data, etc., determined at a higher theoretical level, do correlate better with experimental data, than those originating from lower theoretical treatments. The Ramachandran surface of an alanine dipeptide now determined at six different levels of theory [RHF and B3LYP 3‐21G, 6‐31+G(d) and 6‐311++G(d,p)] serves as a suitable test. Minima, first‐order critical points and partially optimized structures, determined at different levels of theory (SCF, DFT), were completed with high level energy calculations such as MP2, MP4D, and CCSD(T). For the first time three different CCSD(T) sets of energies were determined for all stable B3LYP/6‐311++G(d,p) minima of an alanine dipeptide. From the simplest ab initio data (e.g., RHF/3‐21G) to more complex results [CCSD(T)/6‐311+G(d,p)//B3LYP/6‐311++G(d,p)] all data sets were compared, analyzed in a comprehensive manner, and evaluated by means of statistics.

Peptide models XV. The effect of basis set size increase and electron correlation on selected minima of the ab initio 2D-Ramachandran map of For-Gly-NH2 and For-L-Ala-NH2

A total of eleven basis sets from 3-21G to 6-3111++G(d,p) have been used at the HF and MP2 levels of theory for geometry optimizations of the global, γl, (φ = −75 °, Ψ = +75 °) and the second lowest, βl, (φ = −150 °, Ψ = + 150 °) minimum energy conformations of the l enantiomer of HCONHCH(CH3)CONH2. The results showed that due to fortuitous cancellation of correlation and basis set effects, the HF/3-21G energy-difference of these conformers agrees well with the MP2/6-311++G(d,p) energy difference, while the HF/6-311++G(d,p) energy difference converges erroneously toward zero. The other legitimate conformers were optimized at the HF/3-21G, HF/6311++G(d,p), and MP2/6-311++G(d,p) levels of theory. The results showed that one of the minima disappeared at HF/6-311++G(d,p) and one more of the minima did not occur at the MP2/6-311++G(d,p) level of theory. The correlation and basis set effects stabilized the higher energy conformers.

Phosphorylation loops in synthetic peptides of the human neurofilament protein middle-sized subunit

Peptides containing 13 and 39 amino acid residues and serine-side-chain-phosphorylated (P) analogues thereof, corresponding to human neurofilament protein middle-sized subunit (NF-M), have been synthesized in order to localize the phosphorylation site of this protein. The secondary structure of the nonphosphorylated peptides, determined by circular dichroism (CD) measurements, predicted secondary structural calculations and energy conformational calculations, was suggested to be a series of alternating type I (III) β-turns and 310 or α-helices. By contrast, the phosphorylated peptides exhibit a unique conformation, probably due to salt bridges between the phosphoserine and the lysine residues. This has provided the first clear evidence that phosphorylation induces conformational changes among these synthetic peptides and presumably, in NF proteins as well. These phosphorylation loops might be the major recognition sites of the neurofilament protein-directed kinases.

Peptide and protein folding

Abstract Ab initio peptide folding, and its role in the reductionistic approach towards the understanding of protein folding are discussed from the points of view of past, present and possible future developments. It is believed that after the initial holistic approach, we are now at a new epoch, which will be dominated by reductionism. New quantitative mathematical models will be the result of the reductionistic approach that will lead toward a new, more sophisticated holistic era.

The mechanism of the reverse recovery step, phosphate release, and actin activation of Dictyostelium myosin II.

The rate-limiting step of the myosin basal ATPase (i.e. in absence of actin) is assumed to be a post-hydrolysis swinging of the lever arm (reverse recovery step), that limits the subsequent rapid product release steps. However, direct experimental evidence for this assignment is lacking. To investigate the binding and the release of ADP and phosphate independently from the lever arm motion, two single tryptophan-containing motor domains of Dictyostelium myosin II were used. The single tryptophans of the W129+ and W501+ constructs are located at the entrance of the nucleotide binding pocket and near the lever arm, respectively. Kinetic experiments show that the rate-limiting step in the basal ATPase cycle is indeed the reverse recovery step, which is a slow equilibrium step (kforward = 0.05 s–1, kreverse = 0.15 s–1) that precedes the phosphate release step. Actin directly activates the reverse recovery step, which becomes practically irreversible in the actin-bound form, triggering the power stroke. Even at low actin concentrations the power stroke occurs in the actin-attached states despite the low actin affinity of myosin in the pre-power stroke conformation.

PEPTIDE MODELS XXII. A CONFORMATIONAL MODEL FOR AROMATIC AMINO ACID RESIDUES IN PROTEINS. A COMPREHENSIVE ANALYSIS OF ALL THE RHF/6-31+G CONFORMERS OF FOR-L-PHE-NH2

Abstract Phenylalanine is expected to have conformational features similar to the other three naturally occurring aromatic amino acid residues: Tyr, Trp and His. Previous ab initio structure determinations resulted in 19 different conformers of HCO–L–Phe–NH2 at the RHF/3–21G level of theory. The present work summarises the results of a comprehensive analysis incorporating RHF/3–21G, RHF/6–31+G*, RHF/6–31+G*//RHF/3–21G and B3LYP/6–311++G**//RHF/3–21G data as some of the previously established minima have vanished with the larger basis set, three out of the 19 stationary points having migrated during the optimisation. On top of that, the conformational building unit of the right-handed helix-like (αL) conformation and that of the polyproline II (eL) conformation are still missing from the E=E(φ,ψ) surface. The optimised ab initio structures are also analysed in the context of –Phe– conformers taken from a large X-ray database on non-homologous proteins incorporating a total of 158 664 amino acid residues.

Local structural preferences of calpastatin, the intrinsically unstructured protein inhibitor of calpain

Calpain, the calcium-activated intracellular cysteine protease, is under the tight control of its intrinsically unstructured inhibitor, calpastatin. Understanding how potent inhibition by calpastatin can be reconciled with its unstructured nature provides deeper insight into calpain function and a more general understanding of how proteins devoid of a well-defined structure carry out their function. To this end, we performed a full NMR assignment of hCSD1 to characterize it in its solution state. Secondary chemical shift values and NMR relaxation data, R 1, R 2, and hetero-NOE, as well as spectral density function analysis have shown that conserved regions of calpastatin, subdomains A and C, which are responsible for calcium-dependent anchoring of the inhibitor to the enzyme, preferentially sample partially helical backbone conformations of a reduced flexibility. Moreover, the linker regions between subdomains are more flexible with no structural preference. The primary determinant of calpain inhibition, subdomain B, also has a non-fully random conformational preference, resembling a beta-turn structure also ascertained by prior studies of a 27-residue peptide encompassing the inhibitory region. This local structural preference is also confirmed by a deviation in chemical shift values between full-length calpastatin domain 1 and a truncated construct cut in the middle of subdomain B. At the C-terminal end of the molecule, a nascent helical region was found, which in contrast to the overall structural properties of the molecule may indicate a previously unknown functional region. Overall, these observations provide further evidence that supports previous suggestions that intrinsically unstructured proteins use preformed structural elements in efficient partner recognition.