Background of the Invention: Human beings have had a long battle against cancer.

Because the disease is so widespread, manifests itself in so many different ways and is so relentless, the potential market for effective cancer therapies is enormous. It is estimated that 10 million people in the U. S. either have or have had cancer. The National Cancer Institute (NCI) projected that in 1995, some 1.2 million new cases of. cancer will be diagnosed in the United States, and that 538,000 people will die of the disease.

Cancer is currently treated, with a low degree of success, with combinations of surgery, chemotherapy and radiation. The reason for the low degree of success in chemotherapy is because current chemotherapeutic approaches target rapidly dividing tumor cells. This approach is ineffective against cancer that is dormant or slow growing. Such treatments also affect other, noncancerous cells that divide rapidly, thereby causing harmful side effects.

Only in the last several years has a new approach emerged in the battle against cancer. This approach is based on the newly discovered biological phenomenon called"Apoptosis".

Apoptosis is also called"programmed cell death"or"cell

suicide". (Krammer, et al. ,"Apoptosis in the APO-1 System", Apoptosis: The molecular Basis of Cell Death, pp. 87-99 Cold Spring Harbor Laboratory Press, 1991). In contrast to the cell death caused by cell injury, apoptosis is an active process of gene-directed, cellular self-destruction that serves a biologically meaningful function. (Kerr, J. F. R and J. Searle J. Pathol. 107: 41,1971). One example of the biologically meaningful functions of apoptosis is the morphogenesis of embryo. (Michaelson, J. Biol. Rev. 62: 115,1987). Just as the sculpturing of a sculpture needs the addition as well as removal of clay, the organ formation (Morphogenesis) of an embryo relies on cell growth (addition of clay) as well as cell death (removal of clay). As a matter of fact, apoptosis plays a key role in the human body from the early stages of embryonic development through to the inevitable decline associated with old age. (Wyllie, A. H. Int. Rev. Cytol. 68: 251,1980). The normal function of the immune, gastrointestinal and hematopoietic system relies on the normal function of apoptosis. When the normal function of apoptosis goes awry, the cause or the result can be one of a number of diseases, including: cancer, viral infections, auto-immune disease /allergies, neurodegeneration or cardiovascular diseases.

Because of the role apoptosis plays in human diseases, apoptosis is becoming a prominent buzzword in the pharmaceutical research field. Huge amounts of time and money are being spent in an attempt to understand how it works, how it can be encouraged or inhibited and what this means for practical medicine. A handful of companies have been formed with the prime direction of turning work in this nascent field

into marketable pharmaceutical products. The emergence of a core of innovative young companies combined with the tentative steps being taken by established industrial players are certain to make apoptosis research one of the fastest-growing and most promising areas of medical study.

The idea that cancer may be caused by insufficient apoptosis arose relatively recently (Cope, F. O. and Wille, J. J.,"Apoptosis" : The Molecular Basis of Cell Death, Cold Spring Harbor Laboratory Press, p. 61,1991). This idea opened a door for a new concept in cancer therapy---Cancer cells may be killed by encouraging apoptosis. Apoptosis modulation, based on the processes present in normal development, is a potential mechanism for controlling the growth of tumor cells.

Restoring apoptosis in tumor cells is an attractive approach because, at least in theory, it would teach the cells to commit suicide. Nevertheless, since the objective of cancer treatment is to kill cancer cells without killing the host, the success of this treatment is still dependent on the availability of drugs that can selectively induce apoptosis in tumor cells without affecting normal cells. In this patent application, we describe the methods for the isolation of proteins that specifically induce apoptosis in cancer cells without affecting normal cells. These proteins may present a new class of anticancer drugs that induce apoptosis in cancer cells, thus offering a breakthrough in cancer therapy.

Brief Description of Drawings: Fig. 1 shows a slide of LNCaP (prostate cancer) cells without treatment of filtrate containing SEQ ID NO : 1.

Fig. 2 shows a slide of LNCaP cells incubated with filtrate containing SEQ ID NO : 1 for six (6) hours.

Fig. 3 shows an additional slide of LNCaP (prostate cancer) cells without treatment of filtrate containing SEQ ID NO : 1.

Fig. 4 shows a slide of LNCaP cells incubated with filtrate containing SEQ ID NO : 1 and which expressed membrane bubbling, which is an indicator of cells undergoing apoptosis.

Fig. 5 shows a slide of LNCaP cells without filtrate containing SEQ ID NO : 1.

Fig. 6 shows a slide of LNCaP cells, which were incubated with filtrate containing SEQ ID NO : 1 for three (3) hours and expressed membrane"bubbling,"which is an indicator of cells undergoing apoptosis.

Fig. 7 is a graph of SEQ ID NO : 1 (Fragment nM) versus the percent apoptosis in HT-29, CCD-18 Co, and LNCaP cells.

Fig. 8 is a graph of the time of incubation of SEQ ID NO : 1 filtrate versus percent apoptosis in HT-29 and CCD-18 Co cells.

Detailed Description of the Invention: 1. Isolation of Bovine Fetuin and the Apoptotic Effect Thereof in Tumor Cell Lines.

Fetuin is mainly a fetal protein, in the sense that the highest concentrations are found in serum and body fluids of embryos and fetuses. For example, the concentration of fetuin in bovine serum drastically decreases, probably within a few days after birth, to 1-2% of the fetal level. (Yang, et al., Biochim. Biophy. Acta. 1130,149-156 1992). A histochemical study has shown that fetuin may control tissue remodelling and

physiological cell death during embryonic development. (Von Bulow, et al. , Histochemistry 99: 13-22,1993). This result raises the possibility that fetuin may contain activity inducing cell death (apoptosis).

Therefore, fetuin was prepared and tested for apoptotic activity. Interestingly, results illustrated that only bovine fetuin prepared by a special method is able to induce apoptosis in tumor cell lines. The commercial fetuin that is prepared by ammonium sulfate precipitation and EDTA treatment was found to contain a very low activity in inducing apoptosis in tumor cells.

1A. Preparation of Bovine Fetuin.

Bovine fetuin was prepared by the modified Spiro method (Spiro R. G. , Journal of Biological Chemistry 235,10 : 2860, 1960) according to the following steps: 1. One hundred milliliters of Fetal Bovine Serum (FBS).

2. Add two hundred milliliters of 0.05 M Zinc Acetate containing 30% (V/V) ethanol, adjust to pH 6.4 by 1M NH40H- NH4C1, let stand 15 hours at-5° C.

3. Collect the supernatant by centrifugation, add 1.0 M Barium Acetate and 95% ethanol to give 0.03 M Barium Acetate, 25% ethanol. Let stand 2 hours at-5°C.

4. Collect the supernatant by centrifugation, add 95% ethanol to give 40% ethanol. Let stand 15 hours at-10°C.

5. Collect the precipitate. Dissolve the pellet by phosphate buffer saline.

The purified fetuin showed a single protein band with apparent molecular weight of 63 Kd on SDS-PAGE.

1B. Induction of Apoptosis in Tumor Cell Lines Using Bovine Fetuin.

Fetuin purified from fetal bovine serum by the procedure described above was dissolved in phosphate buffer saline (PBS).

The free Zinc Acetate and Barium Acetate were removed by repetitive concentration. Fetuin was tested in LNCaP and HL-60 cells. LNCaP or HL-60 (1,000 cells) was seeded 10 microliters RPMI containing 15% or 20% Fetal bovine serum, penicillin and streptomycin at 37 degree, 5% C02 in microtray plates (25 1 wells, Robbins Scientific Corp. ). Fetuin (in 10 all PBS) at concentration of 100 ng/ml was added 3-4 hours after cells were seeded. After incubation of the tested sample with cells for 15 hours, two microliters of Hoechst dye (0.03 ng/ml in PBS) was added. Two hours later, cells that were stained with Hoechst dye were examined under fluorescence microscope. The nuclei of apoptotic cells showed DNA condensation and fragmentation, which was easily identifiable by Hoechst dye staining. The percentage of apoptotic cells was calculated by the following equation: % Apoptotic cells=Number of cells with DNA condensation and fragmentation Total cell number The nuclei of the LNCaP cells that were incubated with the control sample (PBS) were normal and healthy. However, the nuclei of the LNCaP cells that were been incubated with fetuin (100 ng/ml in PBS) showed the characteristics of apoptosis.

First, the cells in the presence of fetuin showed condensation of the nucleus, as demonstrated by the more intense fluorescent light compared with the control nucleus. Second, the nucleus condensation was accompanied by the fragmentation of DNA,

demonstrated by the breakage of nucleus. As the condensation of the nucleus and the DNA fragmentation are the two morphological characteristics of cells under apoptosis, these results suggest that fetuin contains an activity inducing apoptosis in LNCaP cells.

Similarly, the nuclei of the HL-60 cells that were incubated with control buffer (PBS) were normal and healthy.

However, the nuclei of the HL-60 cells that were incubated with fetuin showed the characteristics of apoptosis. Fetuin caused condensation of the nucleus as demonstrated by the more intense fluorescent light compared with the control nucleus. Second, the nucleus condensation was accompanied by fragmentation of the DNA, as demonstrated by the breakage of the nucleus. As we have mentioned above, the nucleus condensation and DNA fragmentation are the two morphological characteristics of cells under apoptosis. Therefore, these results suggest that fetuin contains an activity inducing apoptosis in HL-60 cells.

1C. Bovine Fetuin Selectively Induces Apoptosis in Cancer Cells Without Having an Effect on Normal Cell Lines.

We compared the effect of fetuin on the induction of apoptosis in various cell lines. At a concentration of 50 g/ml, fetuin prepared as described above strongly induced apoptosis in the following tumor cell lines: LNCaP (prostate cancer), PC-3 (prostate cancer), HL-60 (leukemia), MCF-7 (breast cancer), Colo 205 (colon cancer), Calu-1 (lung cancer).

Fetuin was found to be inactive in inducing apoptosis in CCD 39 Lu cells (normal lung fibroblast) at concentrations (25 Rg/ml) that highly induced apoptosis in LNCaP (prostate cancer), HL-60 cells (leukemia), and MCF-7 cells (breast

cancer). Fetuin (25 g/ml) prepared as described above was incubated with CCD 39 Lu cells grown in MEM in a microtray plate for 15 hours. The CCD 39 Lu cells remained morphologically unchanged in the presence of fetuin.

1D. Only Fetuin Prepared by the Method Described Above is Able to Induce Apoptosis in Tumor Cell Lines.

Fetuin purchased from Sigma has a very low activity in inducing apoptosis in LNCaP cells. However, fetuin (25 pg/ml) prepared in our laboratory by the method described in Section 1A above induces apoptosis in LNCaP cells by up to 90% in 4 hours. For the fetuin purchased from Sigma, apoptosis inducing activity was observed only at a very high concentration (>250 Rg/ml) over a long incubation period (2 days). Initially, it was estimated that the activity of fetuin prepared in our laboratory was more than fifty thousand folds higher than that of fetuin prepared by other methods.

In the years of research following these original findings, it is conservatively estimated that the fetuin as prepared in Section 1A has more than one hundred times greater apoptotic activity than fetuin prepared by other methods.

While this is not as dramatic as the 50,000 times increase as originally reported, it still represents a significant apoptotic advantage over previously available fetuin in terms of incubation time and LD50 values.

An examination of the preparation methods for Sigma fetuin reveals that these fetuins are prepared by methods including ammonium sulfate precipitation and EDTA treatment. Both treatments may cause the deprivation of the Zinc ion from the

protein, which may cause the irreversible loss of the protein activity.

1E. Effect of Fetal Fetuin on Leukemia Cells In Vivo.

Our previous data demonstrated that fetuin induced apoptosis in cancer cells in vitro. The data provided below shows the success of in vivo testing of fetuin in mice having leukemia. The results show that fetuin has an anti-leukemia effect in mice. Table 1 represents test data illustrating the use fetal fetuin on mice bearing leukemia and shows the increase in survival of leukemia-bearing mice treated with fetal fetuin.

Method Forty DBA/2 female mice (17-20 grams; Simonsen Laboratories, Inc. , Gilroy, CA) kept on a standard diet and water ad libitum were inoculated with tumor cell line P388D1 (ATCC cell line number CCL46). The mice were randomly segregated into groups of ten (10). Zinc-charged fetal fetuin (10 mg/ml) were intraperitoneally injected into group I at 0.002 ml/mouse, group II at 0.02 ml/mouse and group III at 0.2 ml/mouse. Group IV was the control group, which was injected with 0.5 ml of saline solution. The injections were continued for 10 days. Mortalities were recorded for 60 days. The results were expressed as the percentage increase in life span (ILS): ILS = 100 x Median Life Span Treated-Median Life Span Controlled Life Span Controlled Table 1 shows that while 100% of the untreated leukemia- bearing mice were dead after 24 days, 80% of the mice treated with a high dose of fetuin, namely 100 mg/Kg of fetal fetuin,

survived more than 58 days. This in vivo experiment demonstrates that mice bearing leukemia that are treated with fetal fetuin have an increased life span of 141%.

IF. Method of Preparing Supercharged Zinc Fetuin: The method to prepare fetuin with zinc has been refined and improved. As stated above, fetuin prepared by the method as described in Section 1A above is able to induce apoptosis in tumor cell lines. However, commercial fetuin such as from Sigma is found to have a very low activity in inducing apoptosis in tumor cells and in inducing apoptosis in LNCaP cells. For fetuin from Sigma, apoptosis inducing activity was observed only at a very high concentration (>250 g/ml) and at a long incubation time (2 days), whereas fetuin (25 tg/ml) as prepared in Section 1A above induced apoptosis in LNCaP cells by up to 90% in 4 hours. It was initially estimated that the fetuin as prepared as described in Section 1A is more than fifty thousand times higher than that fetuin prepared by other methods. The radically different results suggest a fundamental difference in the chemical composition of commercially available fetuin and the fetuin prepared in accordance with the procedure in Section 1A.

In the years of research following the original findings, I have observed that fetuin from Sigma induces apoptosis at a very high concentration ( » 5 mM) and at a long incubation time (2 days), whereas fetuin (approximately 50 ZM) as prepared in Section 1A above induced apoptosis in LNCaP cells by up to 90% in 4 hours. It is conservatively estimated that the fetuin as prepared in Section 1A has more than one hundred times greater apoptotic activity than fetuin prepared by other methods.

While this is not as dramatic as the 50,000 times increase originally reported, it still represents a significant apoptotic advantage over previously available fetuin in terms of incubation time and LD50 values.

Examination of the methods used to prepare commercially available fetuin revealed that ammonium sulfate precipitation and EDTA treatment was used in preparing fetuin. It was speculated that this ammonium sulfate precipitation and EDTA treatment might result in the deprivation of the ions from the protein and cause irreversible loss of the protein activity.

However, it was not known whether it was the loss of zinc alone, or in combination with the loss of another ion (s), that caused the decreased apoptotic activity in commercially available fetuin. While it was determined that Fetuin-Ca is inactive in inducing apoptosis (data not shown), and barium occurs in only trace amounts, to determine which ion, or combination of ions, were most effective in increasing the apoptotic ability of fetuin, fetuin as prepared in Section 1A above was treated with a chelating agent, such as EDTA, to strip all the inorganic ions, including zinc, calcium, and barium from the protein. After removing these inorganic. ions, the"naked"fetuin was treated or incubated with 0.5 M Zinc Acetate to reload or to bind the fetuin with zinc only. The results of this refinement process are shown in examples in Tables 2-3 in determining the LD50 value. Tables 2-3 show that the improved preparation of Fetuin-Zn or"supercharged zinc fetuin"enhanced fetuin's ability to induce apoptosis in cancer cells by three to four times as compared with the original fetuin bound with zinc as prepared in Part 1A. It is

hypothesized that the fetuin previously bound up with calcium and barium created an inactive form of the protein. By stripping out all ions and replacing them with zinc, inactive fetuin molecules were converted to an active form, thereby explaining the dramatic increase in apoptotic activity. Such supercharged zinc fetuin is a valuable step forward in the fight against cancer.

In one preferred embodiment of this preparation process: 1. Incubation Mixture: 700 Ag of fetuin (0.2 ml; as prepared by the method as described above in Section 1A) was incubated with 0.5 ml of 0.1 EDTA for approximately one (1) hour.

2. Concentration: Add 1.5 ml of saline solution to this incubation mixture and concentrate to near dryness using a molecular or molecule sieve and centrifugal force. Repeat this procedure four (4) times, so that most of the inorganic ions are removed. This"naked"fetuin will be retained on the top of the filter (molecular sieve).

3. Incubate the"naked"fetuin (0.2 ml) with 0.5 ml of 0.5 M Zinc Acetate for approximately three (3) hours.

4. Remove the free Zinc Acetate using the combination of the saline solution, the molecular sieve, and centrifugal force as described in Step 2 above.

2. A SPECIFIC PEPTIDE FRAGMENT FROM FETUIN-ZINC THAT CAUSES APOPTOSIS IN CANCER CELLS. a. Preparation of Fetuin Fragment: As described above in Section 1F (Method of Preparing Supercharged Zinc Fetuin), zinc charged fetuin or supercharged zinc fetuin was prepared by pre-treatment of fetal bovine

fetuin with a chelating agent (EDTA) to remove the inorganic ions, including zinc, calcium, and barium ions, from the fetuin. The resulting stripped fetuin was incubated with 0.5 M Zinc Acetate in order to"supercharge"or load the fetuin with zinc. Three hundred (300) micrograms of the zinc charged fetuin was dissolved in a 50 1 saline solution and then dried in a tube under a vacuum. It is hypothesized that this drying step breaks apart the zinc charged fetuin into peptide fragments.

The dried fragments (of zinc charged fetuin) were reconstituted in 50 p1 water. This fragment solution was passed through a molecular sieve membrane having a molecular weight cut-off of 10,000 daltons. The resulting filtrate of fragments was collected and tested on cells in an apoptosis assay. As shown in Fig. 2, when LNCaP cells are incubated with the zinc charged fetuin fragment filtrate for six (6) hours, the LNCaP cells detach and die. Compared with the control (LNCaP with no filtrate) as shown in Fig. 1, Fig. 2 shows that incubation of the prostate cancer cells with the zinc charged fetuin filtrate causes apoptosis of the cancer cells. Fig. 4 shows that the zinc charged fetuin filtrate treated LNCaP cells also exhibit membrane"bubbling, "which is a characteristic typical of cells undergoing apoptosis. Fig. 3, which shows LNCaP cells without the zinc charged fetuin filtrate, lacks this membrane"bubbling"and characteristic of apoptosis. b. Is Protease Sensitive.

Additionally, the apoptosis-inducing activity of SEQ ID NO : 1 was found to be protease sensitive. Incubation of SEQ ID NO : 1 with proteinase K completely removed the apoptosis-

inducing activity. Proteinase K is an enzyme that cleaves peptide bonds; chelating agents such as citrate and EDTA have no effect on the enzyme activity of proteinase K.

After preparing"supercharged"zinc fetuin or zinc charged fetuin as stated in Section IF above, the resulting composition was dried in a tube and under a vacuum. This dried supercharged zinc fetuin was reconstituted in 50 al of water.

This solution was filtered through a molecular sieve membrane (Centricon 10 tube with a molecular weight cut-off: 10,000 daltons). The filtrate was collected and treated with 5 ul (1 unit/Xul) proteinase K for three (3) hours at 37°C. After treatment with proteinase K, the treated filtrate was filtered through a molecular sieve membrane (Centricon 10 tube) in order to remove the proteinase Ka The proteinase K was retained by the membrane, and the treated filtrate passed through the membrane.

To test the effect of a protease on the apoptotic activity of the filtrate, the filtrate treated with proteinase K was tested on cancer cells. These results were compared to the filtrate that was not treated with proteinase K.

The effect of proteinase K on the apoptotic ability of the Fetuin-Zinc fragments is summarized in Table 4. Experiments 1 and 2 were conducted with one set of zinc charged fetuin filtrate, and Experiment 3 was conducted with another set of zinc charged fetuin filtrate. Table 4 shows that incubation with a protease seems to inactivate the apoptotic effect of the zinc charged fetuin fragment. Because a protease, such as proteinase K, cleaves peptide bonds, the test results of Table

4 strongly suggest that a peptide or a protein of fetuin is responsible for the induction of apoptosis in cancer cells. c. The Filtrate Contains Two Major Peptides Derived from Fetuin.

The dried and reconstituted filtrate was found to contain peptide fragments. The amino acid sequence analysis revealed two major peptide fragments in the filtrate: (1) H-T-F-S-G-V-A-S-V-E (amino acid no. 300-309; His Thr Phe Ser Gly Val Ala Ser Val Glu; SEQ ID NO : 1) and (2) S-A-S-G-E-A-F-H (amino acid no. 310-317; Ser Ala Ser Gly Glu Ala Phe His; SEQ ID NO : 2) of fetuin.

To identify which of these peptide fragments is responsible for the apoptosis-inducing activity, the two fragments SEQ ID NO : 1 and SEQ ID NO : 2 were chemically synthesized. Upon in vitro testing of these chemically synthesized peptide fragments, SEQ ID NO : 1 was shown to have the greater apoptotic activity. LNCaP (prostate cancer cells) were incubated with SEQ ID NO : 1. In Fig. 6, chemically synthesized SEQ ID NO : 1 caused membrane"bubbling"in LNCaP cells after three (3) hours of incubation. Incubation of the LNCaP cells with SEQ ID NO : 2 did not show any apoptotic activity or membrane"bubbling."Fig. 5 shows the control of LNCaP cells without SEQ ID NO : 1. These results suggest that the peptide fragment that induced apoptosis and that was present in the filtrate corresponds to SEQ ID NO : 1.

3. CHARACTERIZATION OF SEQ ID NO : 1. a. SEQ ID NO : 1 Selectively Induced Apoptosis In Cancer Cells But Not In Normal Cells.

Previously, it was found that fetuin and zinc charged fetuin induced apoptosis in various cancer cells without affecting certain normal cells. To test whether SEQ ID NO : 1 derived from fetuin retains this selectivity in inducing apoptosis in cancer cells only and not affecting normal cells, various concentrations of SEQ ID NO : 1 were tested on HT-29 (colon cancer), CCD-18 Co (normal colon), and LNCaP (prostate cancer) cells. As shown in Fig. 7, SEQ ID NO : 1 induced apoptosis in HT-29 and LNCaP cells without affecting CCD-18 Co cells. These results suggest that the fragment was similar to fetuin and zinc charged fetuin in selectively inducing apoptosis in cancer cells and not in normal cells. b. SEQ ID NO : 1 Rapidly Induced Apoptosis in HT-29 (Colon Cancer) Cells.

Fig. 8 shows the effect of time on the induction of apoptosis by SEQ ID NO : 1. At four (4) hours, SEQ ID NO : 1 at a concentration of 0.4 AM induced apoptosis in 52% of the HT-29 colon cancer cells. At six (6) hours, almost all of the HT-29 cells were induced to apoptosis. Even with a little more incubation time (from 4 to 6 hours), the apoptotic ability of SEQ ID NO : 1 rapidly increases within this short period of time. c. The Peptide Fragment Derived From Fetuin Is More Potent Than Fetuin or Zinc Charged Fetuin in Inducing Apoptosis.

Previously, the LD50 (dosage for the induction of 50% cell death) for full-length zinc charged fetuin in LNCaP cells was determined to be 3-10 M. However, the LD50 for SEQ ID NO : lwas

determined to be 0.3-0. 4 FM. Hence, with a much smaller LD50 value, a much smaller amount is required to induce the same amount of apoptotic activity in cancer cells than is required with full-length zinc charged fetuin. Further, SEQ ID NO : lis more potent in inducing apoptosis than its parent molecule.

(See Table 5 which is a table of the LD50 values for fetuin and various fetuin fragments, including SEQ ID NO : 1).

Taking into consideration the previous estimates: (1) Fetuin as prepared in Section 1A above is approximately 100 times more powerful than fetuin prepared from other methods; (2) "Supercharged"Zinc Fetuin (zinc charged fetuin) is approximately three to four times more powerful than the fetuin as prepared in Section 1A (see Tables 2-3); and (3) SEQ ID NO : 1 is approximately eight to ten times more powerful than"Supercharged"Zinc Fetuin (see Table 5).

It is estimated that SEQ ID NO : 1 is approximately several thousand times more powerful than fetuin prepared from other methods.

4. OTHER SEQUENCES OF FETUIN FROM OTHER SOURCES.

In addition, peptide sequences were determined from other animal sera, including pig, sheep and mice. K. M.

Dziegielewska, et. al. , Fetuin, 16-17, (R. G. Landes Co. 1995).

These peptide sequences have a similarity of 60-90% with the fetuin isolated from bovine serum. The present application instructs that these similar fetuin peptide sequences will also have valuable apoptotic activity. The peptide sequences for Fetuin amino acid no. 300-09 for other species are:

Human (H-T-F-M-G-V-V-S-L-G; His Thr Phe Met Gly Val Val Ser Leu Gly; SEQ ID NO : 3); Pig (H-S-F-S-G-V-A-S-V-E; His Ser Phe Ser Gly Val Ala Ser Val Glu; SEQ ID NO : 4); Sheep (H-T-F-S-G-V-A-S-V-E; His Thr Phe Ser Gly Val Ala Ser Val Glu; SEQ ID NO : 5); Rat (H-T-F-S-G-V-A-S-V-E; His Thr Phe Ser Gly Val Ala Ser Val Glu; SEQ ID NO : 6); and Mouse (H-A-F-S-P-V-A-S-V-E; His Ala Phe Ser Pro Val Ala Ser Val Glu; SEQ ID NO : 7). Id.

These analogs are also claimed as being taught by the current application.

I. Table 1 Group Number of Mice Dosage Survivors Increased (days) Life Span (ILS) I 10 0.002 ml 1 (31) 29% fetuin Ici 10 0. 02 ml 1 (29) 17.2 % fetuin III 10 0. 2 ml 8 (58) 141 % fetuin IV 10 0.5 mu 0 (24) saline II. Table 2 Type of Fetuin Amount Required to Reach LD50 Fetuin + Zn 130 µM Supercharged Zinc Fetuin 14.3 µM III. Table 3

Type of Fetuin Amount Required to Reach LD Fetuin + Zn 60 µM Supercharged Zinc Fetuin 19. 6 AM IV. Table 4 Experiment Sample Apoptosis 92% Filtrate (10 µl) 1 Filtrate (10 µl) + proteinase K 50% Filtrate (5 µl) 35% 2 Filtrate (5 µl) + proteinase K 0% Filtrate (10 µl) 75% 3 Filtrate (10 µl) + proteinase K 0%

V. Table 5 Type of FetuinAmount Required to Reach LDSo Zinc Charged Fetuin (full length) 3-10 µM SEQ ID NO : 1 0. 3-0.4 µM SEQ ID NO : 2 1 mM