nedjelja, 29. kolovoza 2010.

ATOMIC HEMOGLOBIN CODE(2)




Q6WN29 Hemoglobin subunit beta

Fragment of sequence 147 AA;
 
Number of atoms

M

V

H

L

T

G

.

.

H

K

Y

H

Sum

20

19

20

22

17

10

.

.

20

24

24

20

2702

1

2

3

4

5

6

.

.

144

145

146

147

10878

Amino acid 1 (AC1) = 20 atoms; AC2=19 atoms; AC3= 20 atoms, etc.
 

Figure 1. Group of amino acids from 1 to 147.

Notes: Aforementioned aminoacids are positioned from number 1 to 147. Numbers 1, 2, 3, n... present the position of a certain aminoacid. This positioning is of the key importance for understanding of programmatic, cybernetic and information principles in this protein. The scientific key for interpretation of bio chemical processes is the same for Hemoglobin protein sequences Q6WN29 and as well as for the other proteins and other sequences in biochemistry.

The first aminoacid in this example has 20 atoms, the second one 19, the third one 20, etc. They have exactly these numbers of atoms because there are many codes in the Hemoglobin protein sequences Q6WN29, analog codes, and other voded features. In fact, there is a cybernetic algorithm which it is „recorded“ that the firs amino acid has to have 20 atoms, the second one 19, the third one 20, etc. The first amino acid has its own biochemistry, as does the second and the third, etc. The obvious conclusion is that there is a concrete relationship between quantitative ratios in the process of transfer of genetic information and qualitative appearance, ie, the characteristcs of the organism.

ALGORITHM

We shall now give some mathematical evidences that will prove that in the biochemistry of insulin there really is programmatic and cybernetic algorithm in which it is „recorded“, in the language of mathematics, how the molecule will be built and what will be the quantitative characteristics of the given genetic information.

Arithmetic progression

Step 1 (Amino acids from 1 to 147)

AC1 = 20 atoms; AC2 = 19 atoms; AC3 = 20 atoms;... AC147 = 20 atoms;

[AC1 + (AC1+ AC2) + (AC1+ AC2+ AC3)..., + (AC1+ AC2+ AC3..., + AC147)] = S1;

AC1 = APa1 = 20;

(AC1+ AC2) = (20+19) = APa2 = 39;

(AC1+ AC2+ AC3) = (20+19+20) = APa3 = 59;

(AC1+ AC2+ AC3..., + AC147) = APa147 = 2702 atoms;

APa1,2,3,n = Arithmetic progression of amino acids 1,2,3,n

[APa1+APa2+APa3)..., + APa147)] = (20+39+59…, + 2702) = 199 217;

S1 = 199217;

Example :

Arithmetic progression 1 (APa)

M

V

H

L

T

G

.

.

K

Y

H

Sum

20

19

20

22

17

10

.

.

24

24

20

2702

1

2

3

4

5

6

.

.

145

146

147

10878

I

M

V

H

L

T

G

.

.

K

Y

H

Sum

20

39

59

81

98

108

.

.

2658

2682

2702

199217

1

2

3

4

5

6

.

.

145

146

147

10878

(0+20) = 20; (20+19)=39; (20+19+20) = 59; etc.

Figure 1. Arithmetic progression 1 (APa) of amino acids from 1 to 147.

Notes: By using chemical-information procedures, we calculated the arithmetic progression for the information content of aforementioned aminoacids.

Step 2 (Amino acids from 147 to 1)

AC147 = 20 atoms; AC146 = 24 atoms; AC145 = 24 atoms;... AC1 = 20 atoms;

[AC147 + (AC147+ AC146) + (AC147+ AC146+ AC145)..., +

+(AC147+AC146+AC145..., +AC1)] = S2;

AC147 = APb147 = 20;

(AC147+ AC146) = (20+24) = APb146 = 44;

(AC147+ AC146+ AC145) = (20+24+24) = APb145 = 68;

(AC147+ AC146+ AC145..., + AC1) = APb1 = 2702 atoms;

APb147,146,145, …,1 = Arithmetic progression of amino acids 147,146,145,…1;

[APb147+APb146+APb145)..., + APb1)] = (20+44+68…, + 2702) = 200 679;

S2 = 200 679;

Example:

Arithmetic progression 2 (APb)

Sum

M

V

H

.

.

N

A

L

A

H

K

Y

H

2702

20

19

20

.

.

17

13

22

13

20

24

24

20

10878

1

2

3

.

.

140

141

142

143

144

145

146

147

I

Sum

M

G

D

.

.

D

E

E

A

G

E

G

N

200 679

2702

2682

2663

.

.

153

136

123

101

88

68

44

20

10878

1

2

3

.

.

140

141

142

143

144

145

146

147

(0+20) = 20; (20+24)=44; (20+24+24)=68; etc.

Figure 2. Schematic representation of the arithmetic progression 2 from 147 to 1.

Within the digital pictures in biochemistry, the physical and chemical parameters are in a strict compliance with programmatic, cybernetic and information principles. Each bar in the protein chain attracts only the corresponding aminoacid, and only the relevant aminoacid can be positioned at certain place in the chain. Each peptide chain can have the exact number of aminoacids necessary to meet the strictly determined mathematical conditioning. It can have as many atoms as necessary to meet the mathematical balance of the biochemical phenomenon at certain mathematical level, etc. The digital language of biochemistry has a countless number of codes and analogue codes, as well as other information content. These pictures enable us to realize the very essence of functioning of biochemical processes.There are some examples.


Nema komentara:

Objavi komentar