Investigations into the cross‐reactivity of rabbit antibodies raised against nonhomologous pairs of synthetic peptides derived from HIV‐1 gp120 proteins

Krsmanovic, V.; Biquard, Jean-Michel; Sikorska-Walker, M.; Ćosić, Irena; Des̀granges, Claude; Trabaud, Mary‐Anne; Jf, Whitfield; Durkin, Jon P.; Achour, A.; Hearn, Milton Thomas William

doi:10.1111/j.1399-3011.1998.tb00665.x

Cited by 36 publications

(50 citation statements)

References 44 publications

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“…As was shown in our previous studies of FGF peptidic antagonists [1,11] and HIV envelope agonists [12,13] such de novo designed peptides express the desired biological function.…”

Section: Resonant Recognition Model (Rrm)mentioning

confidence: 99%

Quantum Foundations of Resonant Recognition Model

et al. 2010

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Biomolecular recognition is an open scientific problem, which has been investigated in many theoretical and experimental aspects. In that sense, there are encouraging results within Resonant Recognition Model (RRM), based on the finding that there is a significant correlation between spectra of the numerical presentation of amino acids in the primary structure of proteins and their biological activity. It has been found through an extensive research that proteins with the same biological function have a common frequency in their numerical spectra. This frequency was found then to be a characteristic feature for protein biological function or interaction The RRM model proposes that the selectivity of protein interactions is based on resonant energy transfer between interacting biomolecules and that this energy, electromagnetic in its nature, is in the frequency range of 10 13 to 10 15 Hz, which incorporates infra-red (IR), visible and a small portion of the ultra-violet (UV) radiation. In this paper, the quantum mechanical basis of the RRM model will be investigated using the solution in the simplified framework of Hückel-like theory of molecular orbits.

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“…As was shown in our previous studies of FGF peptidic antagonists [1,11] and HIV envelope agonists [12,13] such de novo designed peptides express the desired biological function.…”

Section: Resonant Recognition Model (Rrm)mentioning

confidence: 99%

Quantum Foundations of Resonant Recognition Model

et al. 2010

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“…A number of amino acid indices (402 have been published up to now [9]) have been found to correlate in some way with the biological activity of the whole protein. Previous investigations [1][2][3][4][5] have shown that the best correlation can be achieved with parameters, which are related to the energy of delocalised electrons of each amino acid. These findings can be explained by the fact that the electrons delocalised from the particular amino acid have the strongest impact on the electronic distribution of the whole protein.…”

Section: Methodsmentioning

confidence: 99%

“…Through an extensive study, the RRM has reached a fundamental conclusion: one RRM characteristic frequency characterizes one particular biological function or interaction [2,3]. Once the RRM characteristic frequency for a particular biological function or interaction has been determined, it is possible to identify then the individual amino acids so called "hot spots", or domains that contribute mostly to the characteristic frequency and thus to protein's biological function as well [3,4]. The RRM is based on the representation of the protein primary structure as a numerical series by assigning to each amino acid a physical parameter value relevant to the protein's biological activity.…”

Section: Methodsmentioning

confidence: 99%

Development of new computational amino acid parameters for protein structure/function analysis within the resonant recognition model

Pirogova

Irena²,

Cosic³

2001 Conference Proceedings of the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Abstract-The Resonant Recognition Model (RRM) is a physico-mathematical model developed for analysis of protein and DNA sequences. Biological function of proteins and their 3D structures are determined by the linear sequences of amino acids. Previously, the electronion interaction potentials (EIIP) of amino acids have been used to determine the characteristic patterns of different proteins independent of their biological activity. In this study, the effect of various other amino acid parameters on periodicity, obtained using the RRM, were assessed. Here, we are proposing new computational amino acid parameters that could be used successfully for protein analysis instead of EIIP within the RRM.

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“…The RRM analysis showed that these regions share the same characteristic frequency f1 (as gp160env proteins), but they also have their own more prominent characteristic at frequency f2=0.219+0.022 [1][2][3]12,13,15].…”

Section: Preliminary Researchmentioning

confidence: 99%

“…Only one common frequency component for all analysed isolates was obtained as prominent peak at frequency f1=0.185+0.001 (signal-to-noise=484) in the crosspectral function (Fig.1). According to RRM concepts, it can be proposed that this frequency characterises the common biological behavior of all analysed proteins [1][2][3][4]12,13,15]. Figure 1 Cross-spectral function of gp160 env proteins from 19 different isolates revealing the characteristic frequency at f1=0.1855.…”

Section: Preliminary Researchmentioning

confidence: 99%

Analysis of HIV proteins using DSP techniques

Ćosić

2001 Conference Proceedings of the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Abstract:-Our previous studies suggested that digital signal processing methods can be used to analyse linear sequences of amino acids to reveal the functional informational within the protein sequence. In this study both spectral and time-frequency methods are applied to the analysis of the functional content of HIV virus envelope proteins. Here, we have identified specific RRM frequency of HIV proteins, predicted active sites in these proteins and compared these predictions with experimentally determined active sites. I INTRODUCTIONThe Acquired Immuno-Deficiency Syndrome, AIDS, is caused by the human immunodeficiency virus (HIV) which predominantly attacks cells having CD4 molecule on their surface. The mechanisms of viral entry and replications are already well known but the mechanism by which cell depletion occurs is still poorly understood and thus there is still no efficient cure for the disease. The first step in the infection of host cells by HIV virus is interaction between HIV envelope protein and the CD4 antigen. HIV envelope protein, gp160 is initially divided into two fragments proteins gp120 and gp41, which then bind to each other to interact with the CD4 cell antigen. This, as any other protein functional interaction, is a specific and selective interaction. The rules governing the coding of the protein's ability to selectively interact with other molecules is yet to be discovered. The Resonant Recognition Model (RRM) [1][2][3][4] is one attempt to identify the selectivity of protein interactions within the amino acid sequence. The RRM proposes that the specificities of protein interactions are based on the resonant electromagnetic energy transfer at the specific frequency for each interaction. The RRM is applied here to analyse HIV virus proteins, their interactions and in particular HIV active sites within HIV envelope proteins.Studies on antiviral activity of peptides from HIV-1 envelope revealed three peptides: DP-107, peptide-637-666 and the most potent, T20, all from gp41 have antiviral activity [5][6][7]. The mechanism by which these peptides inhibit HIV-1 infection is still not known. We have previously analysed inhibitory activity of these peptides, using the RRM model [1,2,15]. Here we use the continuous wavelet transform to predict positions of inhibitory peptides as well as to predict the position of binding site between HIV-env and CD4 antigen in the HIV envelope protein. II METHODS: the Resonant Recognition Model (RRM)The Resonant Recognition Model is based on the finding that there is a significant correlation between spectra of the numerical presentation of amino acid and their biological activity [1][2][3][4]. By assigning the electronion interaction potential (EIIP) value [8] to each amino acid, the protein sequence can be converted into a numerical sequence. These numerical series can then be analysed by appropriate digital signal processing methods (fast Fourier transform is generally used). To determine the common frequency components in the spectra for a group of proteins, th...

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Investigations into the cross‐reactivity of rabbit antibodies raised against nonhomologous pairs of synthetic peptides derived from HIV‐1 gp120 proteins

Cited by 36 publications

References 44 publications

Quantum Foundations of Resonant Recognition Model

Quantum Foundations of Resonant Recognition Model

Development of new computational amino acid parameters for protein structure/function analysis within the resonant recognition model

Analysis of HIV proteins using DSP techniques

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