EP2281202A1

EP2281202A1 - Marker for determining biological ageing

Info

Publication number: EP2281202A1
Application number: EP09734665A
Authority: EP
Inventors: Lenhard Rudolph
Original assignee: Individual
Current assignee: Individual
Priority date: 2008-04-25
Filing date: 2009-04-27
Publication date: 2011-02-09
Also published as: US20110104698A1; JP2011519030A; WO2009130330A1

Abstract

The invention relates to a method for determining the existence and extent of DNA damage and telomere dysfunction in humans and animals, said method comprising the following steps: the quantity or activity of at least one protein marker in a blood or serum sample is determined, the protein being selected from the group consisting of EF1a, chitobiosidases, stathmin and CRAMP.

Description

MARKER TO THE PROXIMITY. THE BIOLOGICAL AGING

The present invention relates to markers which can be used for the determination of biological aging, regenerative capacity and prognosis in age-associated and chronic diseases, in particular markers which can be determined from blood or serum.

The number of elderly and chronically ill people is rising in most countries of the world (1). Determining biological aging, regenerative capacity, or prognosis in chronic and aging-associated diseases is a fundamental medical problem. Biomarkers that can be used to address such issues are currently unavailable. The identification of easily identifiable biomarkers, indicating the biological aging, the regeneration capacity and the disease risk in old age, could be used to improve and individualize therapies (initiation of therapy, choice of therapy, etc.) in old age and in chronic diseases. In addition, such markers can be used to develop drugs, substances, food products / supplements, and behavioral measures that can halt biological aging.

In many age-associated and chronic diseases, early detection is clinically important. Early detection and prognosis estimation is clinically necessary to initiate therapy that is precisely adapted to the specific disease and individual course. This can reduce the risk that patients develop further complications or complications. In addition, invasive therapies in the elderly often also present a risk. Assessing the risk of therapeutic side effects or complications could lead to a better choice of therapy. This appears especially in therapies which require a regenerative reserve of the patient, such as surgery, chemotherapy or radiotherapy.

One of the few biological markers associated with aging, age-associated diseases and chronic diseases is the shortening of telomeres. The telomeres form the end pieces of the chromosomes (2). Shortening of telomeres occurs in human cells with each cell division (3). This limits the proliferation capacity of human cells to 50-70 divisions (3). In humans, telomere shortening occurs as part of aging in almost all tissues (4). Shortening of telomeres correlates with the survival of 60-75 year olds (5). Accelerated shortening of telomeres has been associated with age-associated diseases such as Alzheimer's disease (6), diabetes mellitus (7), cardiovascular disease (8), and tumor development (9). In addition, shortening of telomeres correlates with disease progression and organ failure in chronic diseases such as hepatitis (10) and myelodysplastic syndromes (11).

The determination of the telomere length has not been successful in the clinic so far, since technically complex methods such as Southern blot, quantitative fluorescence in situ hybridization or quantitative PCR must be used for this purpose. In addition, sample collection is often difficult. Telomere shortening in liver tissue correlates with the progression of chronic liver disease to liver cirrhosis (10). It would therefore be necessary to carry out liver biopsies in order to be able to estimate the prognosis and disease progression.

Another problem of telomere length determination is that the telomere length per se has only limited power over cell function and regenerative capacity. Animal experiments have shown that it is not the average telomere length that is decisive, but the number of critically short, dysfunctional telomeres (12). So it comes in the mouse model to a premature Aging and a reduction in organ preservation when the number of dysfunctional telomeres is increased, although the median telomere length may still be relatively long (12). These results are also important for the proliferation capacity of human cells. This leads to the induction of senescence and thus to the irreversible proliferation loss of the cells when the number of dysfunctional telomeres per cell exceeds a certain level (13).

In summary, telomere dysfunction appears to be an indication of aging, age-associated diseases, as well as chronic diseases. However, the determination of telomere dysfunction as a clinical marker was not successful because telomere dysfunction is difficult to determine methodologically and biopsies from the affected organs are often not available.

It was an object of the present invention to provide a method with which a determination of biological aging, regenerative capacity and prognosis in age-associated and chronic diseases can be carried out in a simple manner.

This problem is now solved by the identification of marker proteins which are secreted by cells in response to telomere dysfunction (or other forms of DNA damage) and which can be determined by simple methods in the blood serum.

A group of four proteins secreted by cells in response to telomere dysfunction or DNA damage has been identified (Jiang, Rudolph, Schiffer, Mischak et al., 2008 and unpublished data). These proteins have been identified in the culture supernatant of bone marrow cells from telomerase knockout (Terc ^"Λ ) mice with dysfunctional telomeres, and it has been shown in advance that Terc ^{" Λ} mice develop telomere dysfunction in bone marrow cells and thereby the function of hematopoietic cells Strain and progenitor cells is restricted. To identify marker proteins of telomere dysfunction, bone marrow cells from these mice were cultured (4 hrs). Proteome analysis of the secreted proteins in the cell culture supernatant was then performed by CE-TOF-MS. In this method, four proteins were identified that are specifically associated with the aging of telomere dysfunctional mice.

These proteins are:

1. Elongation Factor 1 alpha: (EF-lalpha): This protein controls transcriptional protein synthesis and is up-regulated in human cells in response to proliferation loss (senescence) (18,19).

2. Chitinase 3 like protein 3 (Chi3L3): This protein belongs to the family of chitinases, which are also activated in response to activation of the innate immune system (15, 16). Upregulation of a member of the chitinase family has been associated with the aging of human cartilage cells (17). Subsequent studies have shown that the determination of the enzyme activity of chitobiosidases, chitinases, chitibiases and / or N-acetyl-glucosaminidases can be used to determine the age and risk of developing age-associated diseases and cancer in humans. All or individual activities of chitobiosidases, chitinases, chitibiases and N-acetyl-glucosaminidases are measured.

3. Catelcidino-Related Anti-Microbial Protein (CRAMP, also referred to as LL-37 in humans): This protein is activated in response to activation of the innate immune system and appears to have a protective function against bacterial infections (14).

4. Stathmin (OP18): This protein controls microtubule stability, cell motility and mitosis (20).

The determination preferably takes place from blood or serum samples. It turns out that these four protein markers are upregulated in different organs of telomere dysfunctional mice (kidney, liver, lung, brain, spleen and heart). In addition, protein expression of these marker proteins in the blood serum of aging mice with dysfunctional telomeres is increased. These markers appear to be specific for aging in telomere dysfunction because upregulation of these marker proteins does not occur in wild-type mice with long telomeres. The work also shows that the same marker proteins in aging human cells (fibroblasts) are upregulated as part of aging and in response to radiation-induced DNA damage in young human cells.

Orthologous proteins of the marker proteins identified in the mouse system are known in humans for three of the four proteins: EF-lalpha, stathmin, CRAMP. An orthologue for Chi3L3 is currently unknown in humans. However, it is possible to determine the enzyme activity of chitobiosidases, chitinases, chitibiases and N-acetylglucosaminidases in human samples. The studies show for the first time that these enzyme activities can be used to determine the age and risk of developing age-associated diseases and cancer. The determination of chitobiosidases is particularly preferred.

An essential feature of aging is the accumulation of DNA damage. In this sense, the accumulation of telomere dysfunction is also to be understood, since in response to telomere dysfunction, activation of DNA damage signaling pathways occurs in cells (21). A number of premature aging syndromes in humans are associated with the mutation of genes necessary for the maintenance of DNA stability. Our own investigations show that the identified marker proteins are also up-regulated in human cells in response to irradiation-induced DNA damage. Thus, in response to radiation, there is a significant upregulation of the marker proteins at the RNA and protein level. To- In addition, an upregulation of the marker proteins in the cell culture medium of irradiated human cells is detectable in comparison with unirradiated human cells.

Furthermore, methods were established to detect the 3 orthologous marker proteins in human blood serum using Elisa. In addition, a commercially available kit for determining the enzyme activity of chitinases, chitibiases and N-acetyl-glucosaminidases in human samples was determined.

Further methods for detecting the marker proteins are quantitative PCRs for the marker proteins. In addition, antibodies were additionally defined which can be used for immunohistochemical detection of the marker proteins in human tissue samples.

The identified proteins are biomarkers of DNA damage, telomere dysfunction and can be used to determine the biological age, regenerative capacity, risk of cancer, the risk of developing age-associated diseases and the prognosis of chronic human and animal diseases. The methods relate to ex vivo examinations of body fluids or biopsies.

The method is applicable to mammals and especially humans. The determination ex-vivo is preferred.

The following objectives can be achieved by the method according to the invention:

1. Determination of the presence of DNA damage and dyfunctional polymers

DNA damage and telomere dysfunction are fundamental mechanisms that can prevent the development of age-associated diseases, aging, regeneration capacity, and cancer formation are underlying. The detection of DNA damage and telomere dysfunction is difficult. There are currently no easily identifiable serum markers that can be determined in the blood or body fluids that indicate the presence of DNA breaks or telomere dysfunction. The defined markers can be used for this application. The studies show for the first time that the identified markers increase in response to telomere dysfunction or DNA damage in the blood serum. Due to the increasing recognition that DNA damage and telomere dysfunction are fundamentally underlying the development of age-associated diseases and cancer, the invention represents a significant advance in medicine and can be used as a novel biomarker.

2. Determination of biological age and expected life expectancy:

The biological age of an individual may differ from the chronological age. It is well known that genetic factors, living conditions, lifestyle habits, eating habits, external factors and many other factors have an influence on the aging of the organism. The biological age determines the life expectancy and fitness of the aging individual in some cases more than the chronological age. Slow-aged, 60-year-old people can be fitter and have a longer life expectancy than aged 50 years old.

Measurement of the expression of the biomarkers defined herein can determine the presence and extent of DNA damage and telomere dysfunction. There is increasing evidence that these two parameters correlate with the biological age of an individual and their expected life expectancy. The measurement can be carried out in body fluids (eg serum, blood, urine, saliva, cerebrospinal fluid) or in tissue and organ biopsies and samples. In addition to the measurement by means of staining, PCR and gene array, the markers can also be determined with modern imaging techniques (molecular imaging). These methods are suitable for determining the state of aging of organs or for identifying aged cell clones with increased risk of degeneration.

The determination of the biological age and the expected life expectancy using these markers is suitable for the following areas:

a) Personal life planning: For individual life planning, it is important to be able to estimate how long you are expected to be fit and able to work and what your own, probable life expectancy is. The determination of the biomarkers defined here can be used to determine the biological age and life expectancy of the individual. This can help the individual with their personal life planning.

b) Medical area: In the medical field, it is important to be able to determine the biological age and the life expectancy of a patient in therapy planning. This is particularly important in invasive therapies (surgery, intensive care, organ transplantation, etc.). The determination of the biomarkers defined here can be used to determine the biological age and life expectancy of the individual. This can help physicians improve their individual therapeutic indications.

c) Lifestyle and Wellness Industry: There is evidence that sports and spa treatments can have a positive impact on aging. Which programs / applications are best suited to stop aging is not known. Moreover, it is not possible to objectively determine the success of such procedures. The determination of the biomarkers defined here can be used to determine the use of such biomarkers To optimize procedures and to assess the success of the measures in the course.

d) Healthy foods / food supplements: There is evidence that the diet can have a beneficial effect on aging. Which foods / supplements are best for whom to stop aging is not known. Moreover, it is difficult to determine the success of such measures. The determination of the biomarkers defined here can be used to optimize the use of such methods and to assess the success of the measures in the course.

e) Medicines / substances to improve fitness, organ function and life expectancy: There is an ever-increasing number of medicines and substances that can have a positive effect on aging and fitness in old age. Which drugs / substances are best suited to stop aging is not known. In addition, it is difficult to determine the success of such drugs / substances. The determination of the biomarkers defined here can be used to optimize the use of such drugs / substances and to assess the success of the measures in the course.

f) Forensic / Criminalistics: The determination of markers defined here can be used to determine the biological age of victims of violent crimes and accidents.

g) Determining the biological age and life expectancy of livestock, pets, sport animals:

The trade in livestock, domestic animals and animals used in sport (eg: racehorses, jumpers, camels, dogs, etc.) is often accompanied by medical reports on the fitness and the expected useful life of the animals. The measurement of the markers defined here can be used determine the biological age and the expected fitness span and life expectancy of animals.

h) Sports Medicine / Professional Sports: The determination of the markers mentioned here can be used to determine the biological age and fitness of athletes.

i) Insurance: The determination of the markers mentioned here can be used to determine the biological age and fitness of policyholders.

j) Occupational / Environmental Medicine: The determination of the markers defined here can be used to determine the influence of certain activities and the influence of environmental factors on the biological aging and fitness of individuals.

3. There is experimental evidence that the accumulation of DNA damage and telomere dysfunction limits the ability of tissues and organs to regenerate. The biomarkers defined here can therefore be used to determine the regeneration capacity of tissues and organs. The measurement may be in body fluids (e.g., serum, blood, urine, saliva, cerebrospinal fluid) or in tissue and organ biopsies / samples. The determination of the ability of organs and tissues to regenerate with the help of these markers is suitable for the following areas:

a) Determination of prognosis and treatment planning in chronic diseases: A number of chronic diseases lead to failure of the affected organs in the final stage. Interindividual profiles can be very different. The prediction of individual history is clinically meaningful to better plan the timing of invasive therapies (eg, organ transplants). The determination of the markers defined here can be used to predict the individual case of chronic Diseases (eg: hepatitis, pulmonary fibrosis, anemia, chronic inflammatory diseases) to determine.

b) Determination of prognosis and treatment planning for acute illnesses and injuries.

A number of acute illnesses and injuries can lead to failure of the affected organs and death of the patient. Interindividual profiles can be very different. The prediction of individual history is clinically meaningful to estimate the timing and benefits of invasive therapies (eg: surgery, intensive care). The determination of the markers defined here can be used to determine the individual prognosis for acute illnesses and injuries.

4. There is increasing evidence that the accumulation of DNA damage and telomere dysfunction determines the risk of occurrence and prognosis of age-associated diseases. The determination of the markers defined here can therefore be used to determine the risk of the occurrence and prognosis of age-associated diseases. The measurement may be in body fluids (e.g., serum, blood, urine, saliva, cerebrospinal fluid) or in tissue and organ biopsies / samples.

The determination of the risk of occurrence and prognosis of age-associated diseases using the markers defined here is suitable for the following areas:

a) Determination of the risk of the occurrence of age-associated diseases: A variety of diseases are associated with aging (vascular disease, diabetes mellitus, dementia, strokes, etc.). It would be of clinical importance to be able to estimate the risk of the occurrence of such diseases in order, if necessary, to start early with preventive or therapeutic measures. see countermeasures begin. The determination of the markers defined here can be used to determine the individual risk of developing diseases associated with aging.

b) Determination of the prognosis of age-associated diseases: A variety of diseases are associated with aging (vascular disease, diabetes mellitus, dementia, strokes, etc.). It would be of clinical importance to be able to estimate the prognosis of such diseases in order to take therapy measures adapted to the individual course. The determination of the markers defined here can be used to determine the individual course and prognosis in age-associated diseases.

5. There is increasing evidence that DNA causes damage and telomere dysfunction for carcinogenesis. The determination of the markers defined here can therefore be used to determine the risk of cancer in chronic diseases and in the context of aging. The measurement may be in body fluids (e.g., serum, blood, urine, saliva, cerebrospinal fluid) or in tissue and organ biopsies / samples.

The determination of cancer risk using the markers defined here is appropriate for the following areas:

a) Determination of cancer risk in the context of aging. In old age, the risk of cancer increases. The markers defined here indicate the risk of cancer in the context of aging. A cancer risk assessment can be used to tailor cancer screening to individual cancer risk.

b) Determination of cancer risk in chronic diseases. Many chronic diseases (eg hepatitis, inflammatory bowel disease) increase the risk of cancer. The defined markers show the individual Ie cancer risk in chronic diseases. A cancer risk assessment can be used to tailor cancer screening to individual cancer risk. In addition, the timing of preventative measures (surgery / transplantation) can be improved.

c) Determining the cancer risk of genetic predisposition and genetic diseases. Many genetic diseases (for example, LiFraumatici syndrome, Adenomatosis poplyposis coli) are associated with an increased risk of cancer. The determination of the markers defined here may indicate the individual cancer risk of genetic predisposition and thus be used to improve cancer screening and improve the timing of preventative measures in these diseases.

d) General Cancer Screening: The "General Cancer Screening" is recommended for many cancers (e.g., colon carcinoma, prostate carcinoma, breast carcinoma) as part of aging, following general medical guidelines at the time and frequency of screening. The individual risk of developing cancer is not included in these measures. The determination of the markers defined here can indicate the individual cancer risk and can be used for an improved "general cancer screening" adapted to the individual risk.

Characteristic description:

Figure 1: The markers of telomere dysfunction and DNA damage are detectable in the blood and indicate the risk of tumors in the context of aging and chronic liver disease.

A) Serum levels of EFlalpha are significantly elevated in the blood of hepatitis C virus infected patients who developed liver cancer during the course of the disease (group 1) compared to patients who did not develop liver cancer in the same observation period (group 2, p = 0.02). B) 85-year-old subjects with elevated serum EFlalpha levels (50% of subjects above the mean serum level = blue line) had a significantly higher risk of developing cancer over 4 years compared to 85-year-olds with lower Eflalpha serum levels (50%) Subjects below the mean serum level = red line, p = 0.002).

C) the chitinase enzyme activity is significantly increased in the blood of hepatitis C virus infected patients who developed liver cancer during the course of the disease (group 1) compared to patients who did not develop liver cancer in the same observation period (group 2, p = 0.02).

D) 85-year-old subjects with elevated CRAMP serum levels (50% of subjects above the mean serum level = blue line) had a significantly higher risk of developing cancer over 4 years compared to 85-year-olds with lower CRAMP serum levels (50% of the total) Subjects below the mean serum level = red line, p = 0.002).

Figure 2: The markers of telomere dysfunction and DNA damage are detectable in the blood and are influenced by the lifestyle (smoking, exercise, obesity).

A-C) Protein levels of EFlalpha and stathmin and chitinase enzyme activity in human blood serum correlate significantly negatively with exercise activity. These data indicate that more physical activity is associated with decreased DNA damage.

D) The protein level of stathmin and the chitinase enzyme activity in human blood serum correlate significantly positive with cigarette smoking (measured in pack years = life years in which a pack of cigarettes was smoked per day). These data indicate that smoking is associated with increased DNA damage.

EG) The protein levels of EFlalpha, stathmin and CRAMP in human blood serum correlate significantly with obesity (measured as Body mass index). These data indicate that obesity is associated with increased DNA damage.

The invention is explained in more detail by the following examples.

example 1

EF-lalpha: The up-regulation of this protein has been linked to the proliferation loss (senescence) of human cells in culture (18,19). A link with human aging and age-associated diseases has not been described. Furthermore, it has not been shown that eflalpha is up-regulated by DNA damage and telomere dysfunction. Furthermore, it has not been shown that eflalpha is up-regulated by DNA damage and telomere dysfunction.

The studies show for the first time that this protein increases in blood serum in response to telomere dysfunction and DNA damage (Jiang et al., 2009). In addition, the work shows for the first time that EF-lalpha protein is detectable in human blood and increases in aging, aging-associated and chronic diseases (Jiang et al., 2009). Thus, the blood serum level of EF-lalpha in elderly people in the nursing home (n = 20, mean age 85 years, EF-lalpha = 1.5 units) is significantly higher than in young people (n = 31, mean age 35 years, EF -lalpha = 1 unit, p = 0.0004). There was a further increase in geriatric patients (n = 72, mean age 73 years, EF-lalpha = 1.7 units, p = 0.0115). The marker also showed increased end-stage expression of chronic diseases (e.g., cirrhosis and myelodysplastic syndromes) in both the blood serum and the affected tissues.

In addition, the studies show for the first time that the serum protein levels of the marker indicate the risk of cancer in old age and in chronic diseases (FIG. 1A). In> 85 year old subjects, the risk was within the 4 years of cancer with increased EF-lalpha serum levels (> median) significantly higher (46/243 subjects developed tumors) than those with lower EF-lalpha serum levels (<median, 22/243 subjects developed tumors, p = 0.001). In addition, serum EF-lalpha levels were significantly higher in liver cirrhotic patients who developed liver cancer during the disease than in cirrhotic patients who did not develop liver cancer (Figure IB).

In addition, our studies show for the first time that the serum protein levels of the marker are significantly influenced by lifestyle habits (sports and obesity, Figure 2A, E).

Example 2

CRAMP (also referred to as LL-37 in humans): The studies show for the first time that this protein in blood serum response to telomere dysfunction increases (22). In addition, our studies show for the first time that this protein increases in human blood in the context of human aging and in the context of age-associated diseases (22). Thus, the blood serum level of CRAMP is significantly higher in old people in the nursing home (n = 20, mean age 85 years, CRAMP = 18ng) than in young people (n = 31, mean age 35 years, CRAMP = 8ng, p <0, 0001). There was a further increase in geriatric patients (n = 72, mean age 73 years, CRAMP = 22ng, p = 0.0007). The marker also shows increased end-stage expression of chronic diseases (e.g., cirrhosis and myelodysplastic syndromes) in both the blood serum and the affected tissues. In addition, the marker indicates the risk of cancer in old age and chronic diseases.

These studies show for the first time that serum levels of CRAMP (LL-37) in human blood in 85-year-old volunteers indicate the risk of developing cancer within the next 4 years (Figure IC). Subjects with elevated CRAMP serum levels (> median) showed significantly higher rates of malignant tumor development (44/243 subjects developed tumors) as the subjects with lower CRAMP serum levels (<median, 24/243 subjects developed tumors, p = 0.006). In addition, CRAMP serum levels were significantly higher in cirrhotic liver cancer patients than in liver cirrhotic patients without liver cancer.

In addition, the studies show for the first time that the serum level of CRAMP is significantly influenced by obesity (FIG. 2G).

Example 3

Stathmin: The studies show for the first time that this protein in blood serum increases in response to telomere dysfunction (22). In addition, the studies show for the first time that this protein increases in human blood in the context of human aging and in age-associated diseases (22). Thus, the blood serum level of stathmin is significantly higher in old people in the nursing home (n = 20, mean age 85 years, STATHMIN = 1.3 units) than in young people (n = 31, mean age 35 years, STATHMIN = 1 unit, p = 0.0001). The marker also showed increased end-stage expression of chronic diseases (e.g., liver cirrhosis and myelodysplastic syndromes) in both the blood serum and the affected tissues.

In addition, the marker indicates the risk of cancer in old age and chronic diseases. Stathmin serum levels are significantly higher in cirrhotic liver cancer patients than in liver cirrhotic patients without liver cancer.

In addition, the studies show for the first time that the serum protein levels of the marker are significantly influenced by lifestyle habits (exercise, smoking and obesity, Figure 2A, D, F).

Example 4

Enzyme activity of chitinases, chitibiases and N-acetylglucosaminidases: An increase in the secretion of chitinase-like protein is described in the cell culture of aged human cartilage cells and in arthritis patients been (17). An increase in the enzyme activity of chitinases, chitibiases and N-acetylglucosaminidases in human blood or in human tissues / organs as a result of DNA damage, telomere dysfunction, aging or diseases has not previously been described.

The investigations show for the first time that the enzyme activity of chitobiosidases, chitinases, chitibiases and N-acetylglucosaminidases increases in the blood serum in response to telomere dysfunction (22). In addition, the studies show for the first time that these enzyme activities in human blood increase in the context of human aging and in age-associated diseases (22). Thus, the enzyme activity of chitinases, chitibiases and N-acetylglucosaminidases in the blood serum of old people in the nursing home (n = 20, mean age 85 years, chitinase enzyme activity = 52 units) is significantly higher than in young people (n = 31 , mean age 35 years, enzyme activity = 24 units, p = 0, 0004). There was a further increase in geriatric patients (n = 72, mean age 73 years, enzyme activity: 56 units, p = 0, 0216). Moreover, the enzyme activity of chitinases, chitibiases and N-acetylglucosaminidases is increased in the end-stage of chronic diseases (e.g., liver cirrhosis and myelodysplastic syndromes) in the blood serum.

In addition, the investigations show for the first time that the enzyme activity of chitobiosidases, chitinases, chitibiases and N-acetylglucosaminidases measured in the blood serum indicates the risk of cancer in chronic diseases. The enzyme activity of chitobiosidases, chitinases, chitibiases and N-acetylglucosaminidases is significantly higher in liver cirrhosis patients with liver cancer than in cirrhotic patients, who developed liver cancer in the course of disease significantly higher than in cirrhotic patients who did not develop liver cancer in the same follow-up period (Figure ID). In addition, the studies show for the first time that chitinase enzyme activity is significantly influenced by lifestyle habits (sport and smoking, Figure 2C, D).

literature

1. Wolfgang Lutz, Warren Sanderson & Sergei Scherbov. The coming acceleration of global population aging. Nature 451, 716-719

2nd Chan SR, Blackburn EH. Telomeres and telomerase. Philos Trans R Soc Lond B Biol Sei. 2004; 359: 109-21.

3. Allsopp RC, Vaziri H, Patterson C, Goldstein S, Younglai EV, Futcher AB, Greider CW, Harley CB. Telomeres length predicts replicative capacity of human fibroblasts. Proc Natl Acad Be U S A. 1992 Nov 1; 89 (21): 10114-8.

4. Jiang H, Ju Z, Rudolph KL. Telomeres shortening and aging. Z Gerontol Geriatry 2007; 40: 314-324.

5. Cawthon RM, Smith KR, O'Brien E, Sivatchenko A, Kerber RA. Association between telomere length in blood and mortality 60 years or older. Lancet. 2003 Feb. 361 (9355): 393-5.

6. Panossian LA, Porter VR, Valenzuela HF, Zhu X, Reback E, Masterman D, Cummings JL, Effros RB. Telomere shortening in T cells correlates with Alzheimers disease status. Neurobiol Aging. 2003; 24: 77-84.

7. Jeanclos E, Krolewski A, Skurnick J, Kimura M, Aviv H, Warram JH, Aviv A. Shortened telomere length in white blood cells of patients with IDDM. Diabetes. 1998; 47: 482-6.

8. Minamino T, Komuro I. Vascular cell senescence: contribution to atherosclerosis. Circ Res. 2007 Jan 5; 100 (l): 15-26.

9. Wu X, Arnos CI, Zhu Y, Zhao H, Grossman BH, Shay JW, Luo S, Hong WK, Spitz MR. Telomere dysfunction: a potential cancer predisposition factor. J Natl Cancer Inst. 2003 Aug 20; 95 (16): 1211-8.

10. Wiemann SU, Satyanarayana A, Tsahuridu M, Tillmann HL, Zender L, Klempnauer J, Flemming P, Franco S, Blasco MA, Manns MP, Rudolph KL. Hepatocyte telomere shortening and senescence are general markers of human liver cirrhosis. FASEB J. 2002; 16: 935-42.

11. Ohyashiki JH, Ohyashiki K, Fujimura T, Kawakubo K, Shimamoto T, Iwabuchi A, Toyama K. Telomere shortening associated with disease evolution patterns in myelodysplastic syndromes. Cancer Res. 1994 JuIl; 54 (13): 3557-60.

12. Heman MT, Strong MA, Hao LY, Greider CW. The shortest telomeres, not average telomere length, is critical for cell viability and chromosomal stability. Cell. 2001 Oct 5; 107 (1): 67-77.

13. Zou Y, Sfeir A, Gryaznov SM, Shay JW, Wright WE. Does a sentinel or subset of short telomeres determine replicative senescence? Mol Biol Cell. 2004 Aug; 15 (8): 3709-18.

14. Nizet V, Ohtake T, Lauth X, Trowbridge J, Rudisill J, et al. (2001). Innate antimicrobial peptide protects the skin from invasive bacterial infection. Nature 414: 454-457.

15. Zhu Z, Zheng T, Homer RJ, Kim YK, Chen Ny, et al. (2004). Acidic Mammalian Chitinase in Asthmatic Th2 Inflammation and IL-13 Pathway Activation. Science 304: 1678-1682. 16. Reese TA, Liang HE, Tager AM, Luster AD, Van Rooijen N, et al. (2007). Chitin induces accumulation in tissue of innate immune cells associated with allergy. Nature 447: 92-96.

17. Dozin B, Malpeli M, Camardella L, Cancedda R, Pietrangelo A. (2002). Response of young, aged and osteoarthritic human articular chondrocytes to inflammatory cytokines: molecular and cellular aspects. Matrix Biol 21: 449-459.

18. Wang E, Moutsatso's IK, & Nakamura T. (1989). Cloning and molecular characterization of a cDNA clone to statin, expressed in nonproliferating quiescent and senescent fibroblasts. Exp Gerontol 24: 485-49

19. Giordano T, Kleinsek D, & Foster DN. (1989). Increase in abundance of a transcript hybridizing to elongation factor I alpha during cellular senescence and quiescence. Exp Gerontol 24: 501-513.

20. Rubin CI, & Atweh GF. (2004). The role of stathmin in the regulation of the cell cycle. J Cell Biochem 93: 242-250.

21. d'Adda di Fagagna et al. (2003). A DNA damage checkpoint response in telomere-initiated senescence. Nature 426: 194-8.

Jiang H, Schiffer E, Song Z, Wang J, Zürbϊg P, Thedieck K, Moes S, Hall N, Bantel H, Jantos J, Brecht M, Jeno P, Hall MN, Hager K, Manns MP, Hecker H, Ganser A, Döhner K, Bartke A, Meissner C, Mischak H, Ju Z, Rudolph KL. Proteins induced by telomere dysfunction and DNA damage represent biomarkers of human aging and disease. Proc Nat Acad Bey 2008, 105: 11299-304

Claims

claims

1. A method for determining the presence and extent of DNA damage and telomere dysfunction in humans or animals, comprising the steps of:

Determining the amount or the activity of at least one protein marker in a blood or serum sample, wherein the protein is selected from the group consisting of EFIα, chitobiosidases, stathmin and CRAMP.

2. A method for determining the state of aging of an organism comprising the following steps:

Determining the amount or the activity of at least one protein marker in a sample, wherein the protein is selected from the group consisting of (i) EFIα, (ii) CRAMP, (iii) stathmin and (iv) chitinase gene family.

3. The method according to claim 2, characterized in that as the activity of the chitinase gene family, the enzyme activity of chitobiosidases chitinases, chitibiases and / or N-acetyl-Glucosaminidasen is measured.

4. The method according to claim 1 to 3, characterized in that the measurement of the expression is carried out by measurement:

- of the protein,

Measurement of fragments of the protein,

Measurement of mRNA encoding the protein

Measurement of mRNA fragments encoding the protein

- Measurement of the biological activity of the protein.

- visual representation of the proteins or the activity of the proteins (molecular imaging)

5. The method according to claim 1 to 3, characterized in that the measurement is carried out in body fluids or in tissue and organ biopsies or - samples.

6. The method according to at least claim 5, characterized in that the body fluids are selected from blood, urine, saliva and Liquori, in particular from serum.

7. The method according to at least one of claims 2 to 6, characterized in that the method for determining the biological age, the probable life expectancy, the ability to regenerate tissues and organs, the risk of occurrence and the prognosis of age-associated diseases, the determination of cancer risk in the case of chronic diseases, the determination of cancer risk in the context of aging, determination of cancer risk in the context of chronic diseases.

8. The method according to at least one of claims 1 to 75, characterized in that 2, 3 or 4 protein markers from the group (i) CRAMP, (ii) EFlα, (iii) stathmin and (iv) chitinase gene family are determined.

9. The method according to claim 8, characterized in that the activity of the chitinase gene family is determined as the enzyme activity of chitobiosidases, chitinases, chitibiases and N-acetyl-Glucosaminidasen.

10. The method according to at least one of claims 1 to 9, characterized in that the markers or the marker activity by imaging (molecular imaging) are presented.