Las pruebas sugieren que las diferencias sexuales en el cerebro son antiguas y evolutivas.

 “Las diferencias entre hombres y mujeres en cuanto a inteligencia y comportamiento han sido objeto de debate y controversia durante décadas.

Ahora, un creciente conjunto de pruebas científicas demuestra que cientos de genes actúan de forma diferente en los cerebros de los seres humanos biológicamente masculinos o femeninos. Aún no está claro qué significa esto, aunque algunos de los genes pueden estar relacionados con trastornos cerebrales relacionados con el sexo, como el Alzheimer y el Parkinson.” “Las diferencias sexuales en la actividad genética del cerebro aparecen temprano en el desarrollo del feto, mucho antes de la pubertad o incluso de la formación de los testículos y los ovarios. Otro estudio de 2025 examinó 266 cerebros fetales post mortem y descubrió que más de 1800 genes eran más activos en los varones y 1300 en las mujeres. Estos conjuntos de genes con sesgo sexual se solapaban con los observados en los cerebros adultos. Esto apunta a efectos genéticos directos de los genes de los cromosomas sexuales, más que a diferencias provocadas por las hormonas.” “Estos patrones de expresión génica sesgados por el sexo no son en absoluto exclusivos de los seres humanos. También se han encontrado en los cerebros de ratas y ratones, así como en monos. El conjunto de genes sesgados hacia el sexo masculino y femenino en los monos se solapa significativamente con el de los seres humanos, lo que implica que los sesgos sexuales se establecieron en un antepasado común hace 70 millones de años. Esto sugiere que la selección natural favoreció las acciones genéticas que promovían comportamientos ligeramente diferentes en nuestros antepasados primates masculinos y femeninos, o quizás incluso más atrás, en el antepasado de todos los mamíferos, o incluso de todos los vertebrados. De hecho, las diferencias de género en la expresión de los genes en el cerebro en desarrollo parecen ser omnipresentes en los animales. Se han observado incluso en el humilde gusano nematodo. “

Las pruebas sugieren que las diferencias sexuales en el cerebro son antiguas y evolutivas.

Differences between men and women in intelligence and behaviour have been proposed and disputed for decades.

Now, a growing body of scientific evidence shows hundreds of genes act differently in the brains of biologically male or female humans. What this means isn’t yet clear, though some of the genes may be linked to sex-biased brain disorders such as Alzheimer’s and Parkinson’s diseases.

These sex differences between male and female brains are established early in development, so they may have a role in shaping brain development. And they are found not only in humans but also in other primates, implying they are ancient.

Gene activity in male and female brains

Decades of research have confirmed differences between men and women in brain structure, function and susceptibility to mental disorders.

We can measure the influence of genetics by looking directly at the activity of genes in the brains of men and women. Now that we have the full DNA sequence of the human genome, it is comparatively easy to detect activity of any or all of the roughly 20,000 genes it contains.

Genes are lengths of DNA, and to be expressed their sequence must be copied (“transcribed”) into messenger RNA molecules (mRNA), which are then translated into proteins – the molecules that actually do the work that underpins the structure and function of the body.

So by sequencing all of this RNA (called the “transcriptome”) and lining up the base sequences to the known genes, we can measure the activity of every gene in a particular tissue – even an individual cell.

When scientists compared the transcriptomes in postmortem tissue samples from hundreds of men and women in 2017, they found surprisingly different patterns of gene activity. A third of our 20,000 genes were expressed more in one sex than the other in one or several tissues.

The strongest sex differences were in the testes and other reproductive tissues, but, surprisingly, most other tissues also showed sex biases. For instance, a subsequent paper showed very different RNA profiles in muscle samples from men and women, which correspond to sex differences in muscle physiology.

A study of brain transcriptomes published earlier this year revealed 610 genes more active in male brains, and 316 more active in female brains.

Genes on the sex chromosomes would be expected to show different activity between men (with an X chromosome and a Y chromosome) and women (with two X chromosomes). However, most (90%) sex-biased genes lie on ordinary chromosomes, of which both males and females have two copies (one from mum, one from dad).

This means some sex-specific signal must control their activity. Sex hormones such as testosterone and oestrogen are likely candidates, and, indeed, many sex-biased genes in the brain respond to sex hormones.

Sex differences in brain gene activity appear early in the development of the foetus, long before puberty or even the formation of testes and ovaries.

Another 2025 study examined 266 post mortem fetal brains and found more than 1,800 genes were more active in males and 1,300 in females. These sets of sex-biased genes overlapped with those seen in adult brains.

This points to direct genetic effects from genes on the sex chromosomes, rather than hormone-driven differences.

Do these differences mean male and female brains work differently?

It would be remarkable if sex differences in the activity of so many genes were not reflected in some major differences in brain function between men and women. But we don’t know to what extent, or which functions.

Some patterns are emerging. Many female-biased genes have been found to encode neuron-associated processes, whereas male-biased genes are more often related to traits such as membranes and nuclear structures.

Many genes are sex-biased only in particular sub-regions of the brain, which suggests they have a sex-specific function only in those regions.

However, differences in RNA levels don’t always produce differences in proteins. Cells can compensate to maintain protein balance, meaning that not all RNA differences have functional outcomes. Sometimes, developmental processes differ between sexes but lead to the same end result.

Brain health

Of particular interest is the finding of a relationship between sex biases and sex differences in the susceptibility to some brain disorders.

Many genes implicated in Alzheimer’s disease are female-biased, perhaps accounting for the doubled incidence of this disease in women. Studies on rodents imply that expression of the male-only SRY gene in the brain exacerbates Parkinson’s disease.

Evolution of sex differences in brain gene function

These sex-biased gene expression patterns are by no means unique to humans.
They have also been found in the brains of rats and mice as well as in monkeys.

The suites of male- and female-biased genes in monkeys overlap significantly with those of humans, implying that sex biases were established in a common ancestor 70 million years ago.

This suggests that natural selection favoured gene actions that promoted slightly different behaviours in our male and female primate ancestors – or perhaps even further back, in the ancestor of all mammals, or even all vertebrates.

https://www.psypost.org/evidence-suggests-sex-differences-in-the-brain-are-ancient-and-evolutionary/